The present invention relates to the detection of nucleic acids sequences in situ using hybridization probes and generation of amplified hybridization signals, wherein background signal is reduced and sensitivity is increased.
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1. A pair of interacting hairpin oligonucleotide probes capable of hybridizing adjacently on a nucleic acid target sequence in fixed and permeabilized cells and interacting to generate a single-stranded initiator sequence capable of initiating a hybridization chain reaction (hcr) or rolling circle amplification (rca) amplification, said probe pair comprising
a first, arm-donating hairpin probe that is a stem-and-loop oligonucleotide having a double-stranded stem comprising two complementary arm sequences flanking a target-sequence-complementary single-stranded loop sequence, wherein one of the arm sequences (donating arm) includes a single-stranded extension, and
a second, arm-acceptor hairpin probe that is a stem-and-loop oligonucleotide having a double-stranded stem comprising two complementary arm sequences flanking a single-stranded loop sequence, the loop and one arm comprising an hcr or rca initiator sequence, the other arm having a single-stranded extension comprising at least a terminal target-sequence-complementary sequence, said second probe being capable of hybridizing to said target sequence adjacently to said first probe,
wherein, when free in solution or bound non-specifically, the probes are capable of maintaining their stem-loop structures,
wherein, hybridization of the first probe's loop sequence to the target sequence opens that probe's stem, but hybridization of second probe's terminal target-sequence-complementary sequence to the target sequence does not open that probe's stem, and
wherein, if the first and second probes are correctly hybridized adjacently on the target sequence, the donating arm of the first probe is single-stranded and capable of hybridizing with the second probe's arm having the single-stranded extension, thereby rendering its hcr or rca initiator sequence single-stranded.
2. The probe pair according to
3. The probe pair according to
5. A set of multiple probe pairs according to
6. A set of two probe pairs according to
a first probe pair that includes an arm-donating probe that hybridizes only to the first allelic variant of said target sequence and an arm-acceptor probe that hybridizes to said target sequence 3′ to where that arm-donating probe hybridizes, wherein said first probe pair interacts to generate a first single-stranded hcr initiator sequence; and
a second probe pair that includes an arm-donating probe that hybridizes only to the second allelic variant of said target sequence an arm-acceptor probe that hybridizes to said target sequence 5′ to where that arm-donating probe hybridizes, wherein said second probe pair interacts to generate a second single-stranded hcr initiator sequence that is different from the first single-stranded hcr initiator sequence.
7. A set of two probe pairs according to
8. An oligonucleotide set comprising at least one pair of probes according to
wherein the initiator sequence generated by each of said at least probe pair, is capable of initiating hcr amplification with said monomer pair.
9. An oligonucleotide set comprising two probe pairs according to
a first pair of hcr hairpin oligonucleotide monomers, both labeled with a first fluorophore of a first color, and a second pair of hcr hairpin oligonucleotide monomers, both labeled with a second fluorophore of a different color,
wherein when free in solution, both monomer pairs are capable of maintaining their hairpin structures, and
wherein the first single-stranded initiator sequence is capable of initiating hcr amplification with the first pair of hcr hairpin monomers but not with the second pair, and the second single-stranded initiator sequence is capable of initiating hcr amplification with the second pair of hcr hairpin monomers but not with the first pair.
10. A sm-FISH method for detecting a target sequence in a sample of cells that include, or are suspected of including, nucleic acid target molecules containing the target sequence, comprising:
a) fixing and permeabilizing cells in the sample;
b) washing the fixed and permeabilized cells;
c) incubating the sample containing the washed cells with at least one pair of interacting hairpin hybridization probes according to
d) optionally, washing the incubated cells to remove unhybridized probes;
e) after step c) or, if included, step d), adding polymerization reagents and incubating to produce an amplified product, said polymerization reagents comprising, for hcr signal amplification, at least one pair of fluorophore-labeled hcr monomers or, for rca signal amplification, at least one circular DNA template and DNA polymerase;
f) washing away excess (unused) hcr hairpin oligonucleotide monomers or excess (unused) rca circular template;
g) for rca signal amplification, adding and incubating a fluorophore-labeled detector probe for each target sequence; and
h) detecting fluorescence in said cells by microscopy or by flow cytometry.
11. The method according to
12. The method according to
a first probe pair that includes an arm-donating probe that hybridizes only to the first allelic variant of said target sequence and an arm-acceptor probe that hybridizes to said target sequence 3′ to where that arm-donating probe hybridizes, wherein said first probe pair interacts to generate a first single-stranded hcr initiator sequence; and
a second probe pair that includes an arm-donating probe that hybridizes only to the second allelic variant of said target sequence and an arm-acceptor probe that hybridizes to said target sequence 5′ to where that arm-donating probe hybridizes, wherein said second probe pair interacts to generate a second single-stranded hcr initiator sequence that is different from the first single-stranded hcr initiator sequence.
15. The probe pair according to
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This application claims priority to U.S. Provisional Application No. 62/510,045 filed on May 23, 2017. The content of the application is incorporated herein by reference in its entirety.
The present invention relates generally to the detection of nucleic acids sequences in situ using hybridization probes and generation of amplified hybridization signals.
Fluorescence in situ hybridization (FISH) is a well-known technique that is used, for example, in detecting RNAs in individual fixed, permeabilized cells. FISH methods to detect cells having low-copy-number RNA targets, that is, detection at the cellular level, typically include signal amplification in order to generate detectable fluorescence. Such methods are reviewed in Moter et al. (2000) J. Microbiol. Meth. 41: 85-112. For example, digoxigenin (DIG)-labeled probes can be detected by the reaction of the DIG label with an anti-DIG antibody coupled to alkaline phosphatase, followed by reaction of the alkaline phosphatase with a substrate in a color-forming reaction. Certain FISH methods have been shown to be capable of detecting single RNA molecules (sm-FISH). Sm-FISH requires the generation of a sufficiently high, localized fluorescent signal that is sufficiently intense and sufficiently above background to enable detection of a single RNA molecule as a detectable fluorescent spot. Two successful methods for sm-FISH utilize sets of multiple nucleic acid hybridization probes for a target sequence, either a small number (five or six) of long, multiply-labeled probes (Femino et al. (1998) Science 280: 585-590) or a large number (e.g., 48) of short probes, all singly-labeled with the same fluorophore, that tile along a target sequence (Raj et al. (2008) Nature Methods 5:877-879). Sets of the latter probes are commercially available as Stellaris FISH probe sets from LGC Biosearch Technologies. Another well-known technique for improving sensitivity sufficiently to enable sm-FISH is signal amplification by the hybridization chain reaction (HCR), a fluorescent signal amplification method developed by Dr. Niles A. Pierce and colleagues of the California Institute of Technology, Pasadena, Calif. (U.S.A.). Yet another technique for improving signal intensities for in situ hybridization reactions is signal amplification by rolling circle amplification (RCA) (Lizardi et al. (1998) Nature Genetics 19:225-232; Soderberg et al (2006) Nature Methods 3:995-1000; and Larsson et al. (2010) Nature Methods 5: 395-7).
In signal amplification by HCR, a linear (or random coil) hybridization probe that includes (or is tagged with) an extension called an “initiator sequence” causes two fluorescently labeled hairpin oligonucleotides (monomers) to polymerize by hybridization, creating a multiply fluorophore-labeled, double-stranded polymer that is tethered to the target sequence complementary to the hybridization probe via its hybridization. Both DNA and RNA have been used to construct the hybridization probe and the HCR hairpin oligonucleotides. A more detailed explanation of HCR appears below in connection with the description of
Variants of the basic HCR method for a single target sequence include the use of a set of multiple probes that carry the same initiator sequence and that hybridize along a target sequence; probes with two initiator sequences, an initiator for a first of the HCR hairpin oligonucleotides on one end and an initiator for the other hairpin oligonucleotide on the other end; or both (Choi et al. (2014) ACS NANO 8: 4284-4294 at 4288, right column). Choi et al. used both: a set of five two-initiator DNA probes per RNA target sequence. Another variant is multiplex detection of multiple target sequences using a set of probes and a different and differently colored pair of HCR monomers for each target sequence. Choi et al., for example, described multiplex detection of five targets using for each target sequence a set of five, two-initiator probes and a unique pair of HCR monomers carrying spectrally distinct Alexa Fluor fluorophores.
Examples of RNA detection in fixed, permeabilized cells (zebra fish embryos) utilizing HCR amplification are reported in Choi et al. (2014). A first method utilized RNA probes (81 nucleotides long, comprising a 50-nucleotide (50-nt) target-complementary or “recognition” sequence, a 5-nt spacer, and a 26-nt initiator sequence) and RNA HCR hairpin oligonucleotide monomers (52 nucleotides long, each comprising a 10-nt toehold sequence, a 16-bp stem, and a 10-nt loop). A second, “next generation” method utilized DNA probes (91 nucleotides long, comprising a 50-nt target-complementary sequence, a 5-nt spacer, and a 36-nt initiator sequence (including a 12-nt toehold-complementary sequence); or 132 nucleotides long, with a spacer and initiator on each end of the target-complementary sequence), and DNA HCR hairpin oligonucleotide monomers (72 nucleotides long, comprising a 12-nt toehold sequence, a 24-base pair (24-bp) stem, and a 12-nt loop). For hybridization with whole-mount zebra fish embryos, the embryos were fixed in 1 mL of 4% paraformaldehyde, washed with PBS, and permeabilized with a series of methanol washes. For RNA probes, hybridization was performed overnight at 55° C. in buffer containing 50% formamide. For RNA hairpin monomers, HCR amplification was overnight at 45° C. in a buffer containing 40% formamide. For DNA probes, the hybridization was performed overnight in buffer containing 50% formamide. For DNA hairpin monomers, hybridization was overnight at room temperature in buffer containing no formamide (only sodium chloride citrate (SSC), Tween 20 and dextran sulfate).
RNA detection in fixed and permeabilized cultured cells, zebrafish embryos, and mouse brain slices using HCR amplification according to Choi et al. (2014) was also reported by Shah et al. (2016). For hybridization with embryos they used a set of thirty-nine one-initiator DNA sm-FISH probes (≥5-nt gaps between probes) comprising a 30-nt target-complementary sequence, a 5-nt spacer, and a 36-nt initiator sequence; for cultured cells and brain slices they used a set of from twenty-one to thirty-two DNA sm-FISH probes comprising a 20-nt target-complementary sequence, a 4-nt spacer, and a 36-nt initiator sequence. HCR amplification conditions were adjusted to limit HCR polymerization to ˜20-to-40 hairpins per polymer chain. For cultured cells HCR amplification was performed for 45 minutes at room temperature with 120 nM of each hairpin monomer in buffer comprising dextran sulfate and SSC. For embryos HCR amplification was performed for one hour at room temperature with 60 nM of each hairpin monomer in buffer comprising dextran sulfate, SSC, and Tween 20. For brain slices HCR amplification was performed for 5-to-6 hours at room temperature with 120 nM of each hairpin monomer in buffer comprising dextran sulfate and SSC.
Current limitations of HCR include the generation of false signals (also referred to as background signals). Tagged hybridization probes that remain non-specifically bound after washing and at the time of initiation of HCR also produce detectable signals that constitute the background signals or false positives. The existence of such signals have been pointed out by several references, although, their methods of determination of background signals were different from each other. Choi et al. (2014) pointed out that the extent of these non-specific background signals depends on the lengths and number of initiator-containing hybridization probes. In their Table S2 Choi et al. (2014) report signal and background levels for one of their HCR detection experiments. The average signal levels were 2010 units, and background levels (referred to as non-specific detection) were 28 units.
Background signals were also observed by Chen et al. (2016) who in their Supplementary Table 3 report signal and background levels in terms of the number of spots that they counted in high magnification imaging. They imaged a region of mouse brain for expression of mRNA from gene Dlg4. The number of spots obtained from using probes complementary to the Dlg4 mRNA was 9,795 in a particular area of the brain. When missense probes (that had the same sequence as in the mRNA and therefore could not bind to the RNA) were used instead, 1,540 spots were detected in the same region. Similarly a probe against a non-existent RNA yielded 1,209 spots in this region. The latter two numbers represent the levels of background signals and the first number represents the specific signals.
Shah et al. (2016) also observed significant background signals created by amplification of non-specifically bound probes tagged with HCR initiators. They analyzed background levels by imaging Pgk1 mRNA simultaneously with three sets of probes: one set of probes tagged with an initiator that elicits signals from one set of HCR hairpins labeled with Alexa 647, a second set of probes tagged with a second initiator that elicits signals from a second set of HCR hairpins labeled with Alexa 594, and a third set of probes that were directly labeled with Cy3b. Their results show that 36% of Alexa 647 and 27% of Alexa 594 HCR and 20% of Cy3b spots stem from non-specifically bound probes (false positive signals) (Figure S3B of Shah et al. 2016). Furthermore, Example 1 of this document describes additional examples of false positive signals that are obtained with HCR performed with passively tagged probes.
A further limitation of HCR is that it cannot be used to distinguish between targets differing from each other by a single nucleotide.
Signal amplification by RCA is normally performed by first forming a circular template in a template-dependent manner from a single stranded linear DNA oligonucleotide that binds to the target in such a manner that its 5′ and the 3′ termini are placed next to each other for a subsequent ligation reaction (Lizardi et al. (1998) Nature Genetics 19:225-232 and Larsson et al. (2010) Nature Methods 5: 395-7). The circular DNA molecule thus created is then used as a template for rolling circle amplification (RCA) by a DNA primer and a DNA polymerase. Copying of the circular template generates numerous concatenated copies of the complement of the template sequence, which is then detected by a fluorescent probe. A more detailed explanation of RCA appears below in connection with the description of
An object of this invention is to reduce background and thereby increase the sensitivity of HCR signal-amplification detection methods.
Another object of this invention is RCA signal-amplification detection methods that generate concatenated amplicons tethered to a hybridization probe, wherein background signal is reduced and sensitivity is increased.
Another object of this invention is an HCR detection method that can be used to distinguish between targets differing from each other by as little as a single nucleotide.
Probes in which an HCR initiator is tagged to a target specific region are known. Although such probes allow amplified detection of in situ hybridization, they are prone to generation of non-specific signals and cannot be used for discrimination and detection of two alleles in the same cell. This invention includes probe pairs in which the HCR initiator is sequestered within hairpins and cannot initiate amplification until the probes are bound to their correct target at the intended location. Furthermore, probe pairs according to this invention allow development and detection of amplified signals from single target molecules that differ from each other by a single nucleotide polymorphism. Both the wild-type and the mutant-type sequence can be detected simultaneously. This invention includes interacting hairpin hybridization probe pairs for initiating signal amplification in fixed and permeabilized cells by HCR.
This invention also includes RCA methods that utilize a probe-tethered primer and a circular template for signal amplification, wherein the primer is included in a probe pair such that it is sequestered within a hairpin and cannot initiate amplification until the probes are bound to their correct target at the intended location. This invention includes interacting hairpin hybridization probe pairs for initiating signal amplification in fixed and permeabilized cells by RCA.
This invention includes oligonucleotide sets of one or more pairs of such probes plus either one or more pairs of HCR oligonucleotide monomers or additional oligonucleotides for RCA. This invention also includes reaction mixtures containing fixed and permeabilized cells and at least one pair of interacting hairpin hybridization probes, reaction mixtures containing fixed and permeabilized cells, hybridized probe pairs that have interacted to generate at least one HCR initiator sequence, and at least one pair of HCR monomers. This invention further includes assay kits for performing a single-molecule fluorescence hybridization (sm-FISH) assay by a method of this invention, wherein a kit contains at least an oligonucleotide set as described above plus at least one buffer for hybridization and amplification reactions. Interacting hairpin probe pairs and HCR monomers comprise natural or modified nucleotides, preferably comprise natural nucleotides, more preferably consisting of DNA nucleotides.
Methods according to this invention are FISH methods for DNA or RNA targets, including particularly methods for, or capable of, single-molecule detection (single-molecule FISH (sm-FISH)). Examples of categories of RNAs include without limitation, messenger RNAs, ribosomal RNAs, small nuclear RNAs, micro RNAs, circular RNAs, non-coding RNAs, pre-RNAs, and spliced or alternatively spliced RNAs. In FISH methods for detecting RNA or DNA in individual cells, cells are probed with hybridization probes after being fixed, permeabilized, and washed. FISH techniques for fixing and permeabilizing cells in cell cultures and tissue are well known, as is washing. Methods according to this invention are not limited to any particular technique for fixing and permeabilizing cells, or to any particular washing step.
In RNA or DNA FISH detection methods according to this invention, fixed and permeabilized cells are probed with at least one pair of interacting hairpin hybridization probes that interact when hybridized adjacently on an RNA or DNA target sequence in an target strand to generate a single-stranded HCR initiator sequence. Such probing comprises incubating the at least one probe pair with the fixed and permeabilized cells to hybridize the probe pair to their target sequence, and incubating hybridized probes to generate an initiator sequence by their interaction. Both probe hybridization and probe interaction may be performed in a single incubation. Reaction of the initiator, after washing to remove excess unhybridized probes, with one of a pair of HCR hairpin monomers, leads to signal amplification by HCR. Alternatively signal amplification is achieved through RCA.
Each pair of interacting hairpin probes includes a first hairpin-containing probe having segments (nucleic acid sequence elements) in the following order, whether 5′→3′ or 3′→5′: a first hairpin stem arm sequence, a loop sequence complementary to a first subsequence of a selected nucleic acid (RNA or DNA) target sequence, and a second hairpin stem arm that is complementary to the first stem arm that includes a single-stranded extension. We refer to this probe variously as an “arm-donating hairpin probe” or an “arm-donating beacon,” which we sometimes abbreviate as “DB”. We refer to its second stem arm as a “donating arm.” Each pair of interacting hairpin probes also includes a second hairpin-containing probe having sequence elements in the following order, whether 5′→3′ or 3′→5′: a terminal target-complementary sequence that is complementary to a second subsequence of the target sequence adjacent to the first subsequence, a first hairpin stem arm sequence that is complementary to the donating arm of the first hairpin-containing probe, a hairpin loop sequence, and a second hairpin stem arm sequence that is complementary to at least a portion of the first hairpin stem arm. We refer to this probe as an “arm-acceptor hairpin” probe or “arm-acceptor probe.” Its second stem arm has a single-stranded extension that includes the terminal target-complementary sequence and in some embodiments also includes a toehold sequence. Regarding orientation, the second hairpin stem arm (the donating arm) of the arm-donating hairpin probe and its complement in the arm-acceptor probe are inward-facing, that is, proximate one another, when the probe pair is hybridized on the target sequence. With reference to the second panel in
The first hairpin-containing probe, the arm-donating probe, functions like a well-known molecular beacon probe, which has a stem-and-loop structure and opens when the loop sequence hybridizes to its complementary target sequence (Tyagi and Kramer (1996) Nature Biotechnology 14: 303-308; Tyagi et al. (1998) Nature Biotechnology 16: 49-53). Hybridization of the loop of the arm-donating beacon to the target sequence separates its stem arms, rendering the second stem arm sequence and its extension single-stranded and thereby able to interact with the second hairpin-containing probe, the arm-acceptor probe. Interaction separates the stem arms of the arm-acceptor probe, rendering its loop sequence and second arm sequence single-stranded and able to function as an initiator for HCR amplification or as initiator (priming sequence) for RCA, as desired.
As noted above, the first arm sequence of the second hairpin-containing probe, the arm-acceptor probe, may include a single-stranded extension of the first arm sequence not only a target-complementary sequence but also, between the stem and the target-complementary sequence, a toehold sequence. In such embodiments (see
Only when the two probes bind, or hybridize, adjacently on the target sequence, do they interact to generate a single-stranded HCR initiator sequence or an RCA primer sequence. If the loop sequence of the second probe is allele-discriminating, that is, it does not hybridize and open the probe if there is a single nucleotide mismatch, and its target sequence includes a nucleotide that differs between alleles, HCR or RCA amplification will result only from the allelic target sequence that is perfectly complementary to the probe.
An important aspect of this invention is that the initiator of amplification is “sequestered” or “masked” in free or non-specifically bound probes but is “revealed” or “unmasked” when the probes are bound to their specific target.
In detection methods according to this invention an HCR initiator sequence generated by a pair of interacting hairpin probes as described above initiates a signal amplification reaction by HCR. In HCR a pair of hairpin oligonucleotide monomers labeled with at least one copy, preferably a single copy, of the same fluorophore, once initiated by reaction with an HCR initiator, interact with one another by hybridization and strand displacement to generate a double-stranded extension of the initiator sequence. The extension is known as an HCR polymer. It is multiply fluorophore labeled, thereby producing an amplified fluorescent signal as compared to a directly fluorophore-labeled probe. It is tethered directly to the arm-acceptor hairpin probe by hybridization and indirectly tethered to that probe's target sequence by hybridization of the probe to the target sequence. A schematic depiction of HCR is shown in
In detection methods according to this invention a single pair of interacting hairpin probes may generate a single copy of an HCR initiator, or additional (one or more) pairs of interacting hairpin probes may be used to generate multiple copies of the HCR initiator. When multiple probe pairs are utilized to detect a single target sequence, the simplest construction is to change only the target-binding sequences, thereby permitting use of a single HCR monomer pair.
In certain embodiments two probe pairs can share a single arm-donating probe. Even though there are only three probes, there are two probe pairs, one pair including the arm-donating probe and a first arm-acceptor probe, and a second pair including the arm-donating probe and a second arm-acceptor probe. In such embodiments one arm-acceptor probe hybridizes to the target sequence 5′ of the binding site of the arm-donating probe, and a second arm-acceptor hybridizes to the target sequence 3′ of the binding site of the arm-donating probe. When the arm-donating probe hybridizes to the target sequence, making its stem arms single stranded, the two freed arms interact with both arm-acceptor probes, thereby releasing two HCR initiators. The two freed HCR initiators then initiate HCR amplification by a single pair of HCR monomers whereby not one but two HCR polymers grow from the common arm-donating probe. This results in a stronger fluorescent signal from a single copy of the target sequence.
Methods according to this invention further include sm-FISH assays, both qualitative and quantitative assays, for both of two allelic variants that differ by as little as a single nucleotide, for example, a wild-type sequence and a mutant sequence containing a single-nucleotide polymorphism or variation (SNP or SNV). Such methods utilize two interacting hairpin probe pairs, wherein each pair contains an arm-donating beacon probe and an arm-acceptor hairpin probe. The loop sequence of each arm-donating beacon probe is complementary to a different allelic variant of the target sequence. For example, the loop sequence of one of the arm-donating beacon probes may hybridize to a wild-type target sequence but not to a mutant sequence having a SNP, and the loop sequence of the second arm-donating beacon probe may hybridize the mutant sequence but not to the wild-type sequence. Thus, for a given RNA target strand, only one of the arm-donating beacon probes will bind to a given target sequence. Although, only one of the arm-donating beacon probes binds to a given target, both arm-acceptor probes bind to the same target, and they do so on either side of the bond arm-donating beacon (
Since both allelic variants may be present on different RNA strands in a heterozygotic cell, signals from both HCR variants will be observed in such a cell. On the other hand, homozygotic cell will exhibit only one of the signals. Finally, in cancer cells in which one of the alleles is amplified relative to the other allele and is expressed to a greater extent, the intensity of the signal of the corresponding HCR will be greater than the intensity of the signal from the HCR corresponding to the minor allele.
Because a single-stranded HCR initiator sequence is not present in a reaction mixture unless it is generated by the interaction of an adjacently hybridized probe pair, the at least one probe pair and the at least one HCR monomer pair can be added together to the fixed and permeabilized cells. However, in certain preferred methods, the at least one probe pair is added first, and unbound probes are removed by washing before HCR monomers are added. sm-FISH methods of this invention include detection of HCR polymers. After HCR polymerization, unused HCR monomers and unbound probe pairs are removed by washing. Fluorescence is detected by microscopic techniques or by flow cytometry.
In some situations rather than targeting the entire mRNA target length with tiled probes for sm-FISH, as is done with tiled Stellaris probe sets of, it may be necessary or advantageous to use a small portion of the target sequence (40-50 nt). For example, in archived formalin-fixed, paraffin-embedded (FFPE) samples the target mRNA may be degraded and be present only as small fragments. In other cases, the target may be a small exon that is not long enough to allow tiling of many sm-FISH probes. In still other cases, the target may include a small variation that needs to be detected. In these cases it will be sufficient and advantageous to use a single pair of interacting hairpin probes or two pairs that share a common arm-donating probe.
The background-free amplification of signals achieved through this invention allows for more reliable detection of target nucleic acids than is achieved by current HCR methods. The reduction in background signals also allows detection of less abundant targets, detection of targets over natural autofluorescence of cells and tissues, and detection of multiple targets in the same cells by combinatorial color-coding. In combinatorial color-coding based multiplexing, each target is detected by using mixtures of probes that give rise to a combination of colors. However, since each target signal is divided in multiple channels, this requires that probes yield strong signals for each channel. The probes of this invention create strong signals to satisfy the needs of combinatorial color-coding based multiplexing.
“RNA”. As used in the specification and claims of this patent application, when referring to a target sequence, “RNA” includes all variants, for example, messenger RNA, ribosomal RNA, coding or noncoding RNA, linear or circular RNA, transfer RNA, microRNA, spliced or alternately spliced RNA, and pre-RNA. As used in the specification and claims of this patent application, when referring to interacting hairpin probes, “RNA” includes oligoribonucleotides with natural ribonucleotides and phosphodiester bonds, and also includes oligoribonucleotides containing one or more non-natural nucleotides (for example, PNA nucleotides, LNA nucleotides or 2′-O-methyl ribonucleotides).
“DNA”. As used in the specification and claims of this patent application, when referring to interacting hairpin probes, “DNA” includes oligodeoxyribonucleotides with natural deoxyribonucleotides and phosphodiester bonds, and also includes oligodeoxyribonucleotides containing one or more non-natural nucleotides (for example, PNA nucleotides, LNA nucleotides or 2′-O-methyl ribonucleotides) and non-natural backbones.
“Nucleic acid.” As used in the specification and claims of this patent application, when referring to a target molecule or target sequence, “nucleic acid” means RNA or DNA, including in either case oligonucleotides with natural nucleotides and phosphodiester bonds; or when referring to interacting hairpin probes, including RNA and DNA oligonucleotides with natural nucleotides and phosphodiester bonds, and also including RNA and DNA oligonucleotides containing one or more non-natural nucleotides (for example, PNA nucleotides, LNA nucleotides or 2′-O-methyl ribonucleotides).
“Adjacently”. As used in the specification and claims of this patent application to describe the hybridization of pairs of interacting hairpin probes, “adjacently” means sites that are sufficiently close to each other to permit interaction between interacting hairpin probes. A preferred choice is “immediately adjacent” in which there is no gap between the binding sites of two interacting probes.
“Target molecule,” “target strand,” “target sequence,” and “target-sequence region” or “subsequence”. As used in the specification and claims of this patent application, a target molecule or target strand is a nucleic acid strand, either RNA or DNA, that contains one or more target sequences. “Target sequence” is a sequence in an RNA or DNA target strand that is being probed, either by one or more conventional passively tagged probes or by one or more pairs of interacting hairpin probes of this invention, where signal amplification leads to a signal of a single color. If a set of two or more conventional passively tagged probes or a set of two or more pairs of interacting hairpin probes target the same target sequence, each conventional passively tagged probe in the set or pair of interacting hairpin probes in the set targets a separate target-sequence region (or subsequence) of the target sequence. In multiplex methods for simultaneously detecting two or more target sequences in the one or multiple target molecules (or target strands), each target sequence is probed by either by one or more conventional passively tagged probes or by one or more pairs of interacting hairpin probes of this invention, where signal amplification leads to a signal of a different color for each target sequence.
“Passively tagged.” As used in the specification and claims of this patent application to describe a hybridization probe that corresponds to probes from the prior art (Choi et al. (2014)), “passively tagged” means that an initiator sequence, whether an HCR initiator sequence or an RCA initiator sequence, is appended to at least one end of the target-sequence-complementary sequence. The initiator in such a probe is not sequestered in a structure that prevents its functioning as an initiator. To the contrary the initiator sequence of a passively tagged hybridization probe can initiate signal amplification whether the probe is bound to its specific target sequence or is bound to a non-specific site.
Interpreting the Drawings
In the Figures sequences that are complementary to one another are designated by the same letter, and one is indicated by a prime (′) to distinguish between complementary sequences. Thus, in the Figures sequences a and a′ are complementary to one another, as are sequences b and b′, I5 and I5′, and so on.
Fluorescence In Situ Hybridization (FISH)
Methods according to this invention are FISH methods. FISH (fluorescence in-situ hybridization) is a well-known method for detecting nucleic acid targets in cells. First cells are fixed, commonly with formaldehyde or paraformaldehyde, and permeabilized, commonly with ethanol or a detergent, to permit introduction of nucleic acid hybridization probes. This invention is not limited to a particular method for fixing and permeabilizing cells; any fixing and permeabilizing method that is compatible with in-situ probe hybridization and HCR or RCA amplification can be used. For example, Choi et al. (2014) teaches fixing embryos with 4% paraformaldehyde and permeabilizing with methanol (Choi et al. (2014) Supplementary Information at S1.1). Shah et al. (2016) Development 143: 2862-2868 teaches fixing mouse brain slices with 4% paraformaldehyde and permeabilizing by the technique known as “PACT clearing”, which includes incubation in a solution of 8% SDS detergent in 1× phosphate buffered saline (PBS) (Shah et al. (2016), Supplementary Materials and Methods. Chen et al. (2016) Nature Methods 13:679-684 and Supplementary Materials, teaches fixing cultured cells with 10% formalin and permeabilizing the fixed cells by storing in 70% ethanol (Chen et al. (2016), Supplementary Methods). In our work reported in the Examples, we used 4% formaldehyde in 1×PBS for 10 minutes for fixation and 70% ethanol for 30 minutes for permeabilization.
In the simplest FISH method a fluorophore-labeled linear (or random coil) hybridization probe complementary to a selected target sequence, for example, a DNA probe, is then added, and unhybridized probe (by which is meant copies of the probe that are not hybridized) is washed away. Fluorescence is then detected. The simplest FISH method suffices only for detecting abundant target molecules. For detecting rare target molecules, particularly for detecting rare target molecules at the single-molecule level, a FISH method must include a way to increase fluorescence emanating from a single target molecule. One general way to do that is signal amplification. This invention relates FISH methods that include either of two signal-amplification methods: the hybridization chain reaction (HCR) and rolling circle amplification (RCA). Methods according to this invention utilize FISH for detection of RNA and DNA targets with a high level of sensitivity, with certain preferred embodiments being capable of single-molecule sensitivity, sometimes referred to as single-molecule FISH (sm-FISH). The discussion below focuses primarily on detection of RNA targets. Particular adjustments that are necessary for DNA detection are described separately.
Hybridization Chain Reaction (HCR)
Certain methods of this invention relate to and employ FISH that includes a signal amplification method known as HCR, the hybridization chain reaction, for detection of single nucleic acid molecules in fixed and permeabilized cells (single-molecule FISH, abbreviated sm-FISH). Detection with conventional HCR signal amplification employs one hybridization probe, or more often, a set of several hybridization probes, for a particular nucleic acid target sequence, for example, an RNA target sequence. Typically the hybridization probe or the multiple hybridization probes in a probe set are not fluorophore-labeled. Each hybridization probe has attached to it a 3′ tail, a 5′tail, or both a 3′ tail and a 5′tail, none of which hybridize to the target sequence. Instead, each tail comprises a terminal HCR “initiator” sequence. We refer to hybridization probes that, when bound to their target sequence, have a free (unsequestered) initiator sequence as “passively tagged probes.” Detection of an RNA target sequence or a DNA target sequence with HCR also employs a pair of fluorophore-labeled hairpin oligonucleotides, sometimes referred to as HCR monomers, one of which interacts with the initiator sequence of the hybridization probe to start HCR amplification. The basics of existing HCR detection methods are shown in
Incubation of HCR monomers H1 and H2 with the sample containing hybridized probe 11 under hybridization conditions causes HCR signal amplification as follows. With reference to the second schematic in
If initiator sequence I2 is included in probe 11 as a 3′ tag (3′-b′-c′-P1), it can also initiate HCR polymerization of the same HCR monomers H1 and H2. Sequence c′ of initiator sequence I2 hybridizes to H2 toehold sequence c as described above to initiate polymerization in the manner described above to create a second HCR polymer that begins with H2 rather than H1 and extends from the 3′ end of probe sequence P1. Also, a set of probes can be made by changing the target-sequence-complementary sequence of probe 11 to hybridize to additional sequences in target sequence TS1.
Sm-FISH with Rolling Circle Amplification (RCA)
This invention also includes reagents and methods for, or capable of, sm-FISH detection that include signal amplification by rolling circle amplification (RCA). We describe first our conception of the manner in which RCA can be used with passively tagged hybridization probes is depicted in
Thereafter RCA is carried out on the sample utilizing a circular DNA template CT that contains sequence I5′ that is complementary to the probe's initiator sequence I5, and also contains detector probe-binding sequence PBS. Template CT and a DNA polymerase are added to the washed sample, which is then incubated under RCA conditions. Initiator (primer) sequence I5 hybridizes to sequence I5′ of template CT as shown in the second schematic in
Methods and Reagents of this Invention with HCR
Detection methods of this invention are sm-FISH methods that include fixing and permeabilizing cells, as described above, hybridizing probes with a nucleic-acid target sequence in the cells, for example an mRNA sequence, and polymerizing a pair of HCR hairpin oligonucleotides (HCR monomers) as described above. Methods of this invention differ from previously known FISH method with HCR amplification in, inter alia, the design and construction of hybridization probes used to initiate HCR polymerization. Rather than using a hybridization probe passively tagged with an initiator sequence, which is capable of initiating HCR whether the probe is hybridized to a target sequence or bound to a non-specific site, methods of this invention use probes of this invention that initiate HCR signal amplification only when hybridized to the intended nucleic acid target sequence, for example, a selected target sequence in an mRNA target molecule. Hybridization probes of this invention comprise a pair of interacting stem-and-loop oligonucleotides that we refer to as a pair of interacting hairpin oligonucleotide probes, preferably composed of DNA, that hybridize adjacently on a nucleic acid target strand's target sequence, which may be a DNA strand or an RNA strand such as an mRNA strand, in a sample that has been fixed and permeabilized by fluorescence in-situ hybridization (FISH) methods.
a. A Pair of Interacting Hairpin Probes of this Invention and their Interaction
An embodiment of pair of interacting hairpin probes according to this invention and a schematic flow chart of their interaction are illustrated in
Sm-FISH methods according to this invention include steps to detect a target sequence in a sample of cells that include, or are suspected of including, target molecules containing the target sequence:
The interacting probe pair depicted in
Shown in
HCR signal amplification is performed following generation of initiator sequence I3 by the method described above. Following interaction of probes 31 and 32 to generate HCR initiator I3, unbound probes are washed away. Then HCR monomers H3 and H4 are added and incubated with the sample under hybridizing conditions. Sequence g′ of freed initiator sequence I3 (
Interacting hairpin probes 31-32 generate HCR initiator sequence g′, f′ (I3) only if the pair hybridize adjacently on target sequence TS3. When free in solution or non-specifically bound, probe 31 is not open and donating arm e′, f′ does not exist in a single-stranded form and thus can't interact with probe 32, which retains its stem-loop structure. Therefore, initiator sequence g′, f′ (I3) is sequestered, that is, not available in a single-stranded form needed to initiate HCR polymerization. First probe 31 is like an unlabeled molecular beacon probe in structure and functioning, both of which are well known. See, for example, Tyagi et al. (1998) Nature Biotechnology 16: 49-53; and Bonnet et al. (1999) Proc. Natl. Acad. Sci. (USA) 96: 6171-6176. Probe 31 is very specific for the intended (correct) target sequence TS3. It can be designed to be either mismatch-tolerant, that is, to hybridize and open even if target sequence TS3 contains one or two mismatched nucleotides relative to loop P3; or it can be designed to be allele-discriminating, that is, to hybridize and open if loop P3 hybridizes to perfectly complementary target sequence TS3, but not to open if target sequence TS3 contains a single mismatched nucleotide relative to loop P3 or if non-specifically bound. Thus, with methods of this invention it is possible to initiate HCR signal amplification from only one of multiple closely related alleles in the target sequence (such as a target sequence containing a single-nucleotide polymorphism (SNP). Probe 32 will not open and generate single-stranded initiator sequence I3 unless hybridized adjacently to an open probe 31. Thus, even though probe 32 is not molecular-beacon type and consequently more apt to bind non-specifically via linear sequence P4, such as to hybridize to a mismatched sequence in target strand 30 or elsewhere in the cellular matrix, probe 32 will not open due to that fact—it must hybridize adjacently to an open probe 31 in order to be opened and generate single-stranded sequence I3. Thus, only if the first probe hybridizes correctly, and only if the second probe hybridizes adjacently to it, which means hybridize correctly, will a single-stranded HCR initiator sequence result. Copies of probe 32 that are in solution or bound non-specifically will not initiate HCR amplification of HCR monomers H3, H4 and will not, therefore, lead to generation of background. Accordingly, methods according to this invention have low background, even embodiments without a washing step between probes hybridization and HCR amplification. However, because a stem hybrid is dynamic and subject to “breathing”, it is possible that very rarely a copy of probe 31 in solution could be open briefly and contact a copy of probe 32, leading to HCR amplification. To guard against that possibility, preferred embodiments of methods of this invention include a washing step prior to the addition of monomers H3, H4 as a precaution against developing even a low level of background signal.
In the design above, the probe sequence in arm-donating beacon 31 is bound by two arms of a hairpin, which, as discussed above, confers higher specificity on the probe. The probe sequence on arm-acceptor probe 32, on the other hand, is a terminal sequence. If the user wants to confer higher specificity on this probe as well, a hairpin forming arm sequence can be added towards the 5′ of probe sequence P4. For example referring to probe 32 in
In the Examples below, we demonstrate successful sm-FISH detection using for a given target sequence a single interacting probe pair that generates an HCR initiator sequence. A set of probe pairs can be made by changing the target-sequence-complementary sequences of both probes so that different pairs hybridize at different places on the target sequence, generate the same initiator, and initiate HCR polymerization with the same pair of HCR monomers to produce a more intense fluorescent signal.
b. Two Interacting Probe Pairs According to this Invention for Two Closely Related Alleles
Certain embodiments of this invention comprise methods to detect, or detect and quantify, either or, if present, both of two closely related alleles, or target-sequence variants. The variation between alleles can include substitution, deletion, or insertion of one or more nucleotides. The variation can also include splice variants. Preferably the variation in the target sequence is contained within the binding region of the arm-donating probe, although, longer variations that span the binding regions of both the arm-donating probe and the arm-accepting probe can also be detected. Detection and quantification can provide single-molecule sensitivity and resolution. Detection of one or, if present, both of two closely related alleles utilizes two pairs of interacting hairpin probes and two pairs of differently labeled HCR monomers, one probe pair and one monomer pair for each allele, is shown schematically in
Shown in
Shown in the top schematic of
Turning to probe pair 48 and 47, the arm-donating hairpin probe 48, is a stem-and-loop oligonucleotide that is allele-discriminating. Its target sequence-complementary loop P5 is perfectly complementary to target-sequence variant WTTS. It includes nucleotide 42 (open circle ◯), which is complementary to nucleotide 43 (open circle ◯) in target sequence WTTS of target strand 41 but mismatched to nucleotide 45 (filled-in circle λ) in target sequence 46. Probe 48 also includes stem d-d′. Stem arm d′, the donating arm, includes terminal, single-stranded extension b′. Probe 47 is an “arm-acceptor hairpin” probe, that is, a stem-and-loop oligonucleotide having a stem b′-b and single-stranded loop sequence a′. One of the arms of the stem, here the 3′ arm b, includes a single-stranded extension comprising target-complementary sequence (or region) P6 and, in the depicted embodiment, also toehold sequence d. The interaction of probes 47, 48 when hybridized adjacently on target sequence WTTS (middle schematic on the left in
It is important to note that the donating arm of each donating beacon probe is longer than its complementary arm. For example, 5′ arm of probe 49 is longer than its 3′ arm, because the 5′ arm contains sequence element f′ in addition to the stem element, sequence e′. If probe 49 binds successfully to target sequence MTTS, as shown in the right-middle schematic in
To be capable of detecting either or both target-sequence variants WTTS and MTTS in a single assay, all four probes of the two interacting probe pairs are incubated simultaneously with a sample containing fixed and permeabilized cells in a hybridization reaction, but, as shown in middle schematics in
Following incubation to permit hybridization and interaction between probes 49, 50 or probes 48, 47, or both, depending on which target sequence or sequences are present in the sample, unhybridized probes are removed by washing, and HCR monomers H3, H4, H1 and H2 are added, resulting in creation of one HCR polymer, or two. Following polymerization, unincorporated (excess) HCR monomers are removed by washing. The availability of single-stranded initiator sequence I1 (that is generated if wild-type target sequence WTTS is present) causes polymerization of HCR hairpin oligonucleotides H1 and H2 (
The binding of arm-donating probe 49 to target sequence MTTS does not cause the stem of adjacently hybridized arm-acceptor probe 47 to open, because the relevant sequences in the two probes are distinct rather than complementary (sequences d in probe 47 and e′ in probe 49 are not complementary, and sequences b in probe 47 and f′ in probe 49 are not complementary). Probe 48 cannot elicit any response from probe 50 for the same reason that probe 49 cannot elicit any response from probe 47.
It will be seen that in probe 48 (
The method of using the interacting probe pairs in
c. An Arm-Donating Beacon Probe that Reveals Two Masked Initiator Sequences and Generates HCR Signal from a Single Pair of HCR Monomers
In order to increase the signals with interacting hairpin probe system, it is advantageous to utilize a set of probes that unmask two HCR initiator sequences, rather than one, for each target sequence. The two initiator sequences will initiate amplification from the same HCR monomer pair and thus produce signals of the same color. An example of such a system is presented in
To overcome the tendency of passively tagged hybridization probes (
Shown in the first schematic in
We note that sequence i′ is present in both probes 71 and 72. Sequence i′ in probe 71 can never serve as a primer, because it's 3′ end is not free (it is connected to sequence e′). Sequence i′ in probe 72 becomes available for binding to the circular template CT only upon interaction of the two interacting hairpin probes when hybridized to their intended adjacent sites on the target sequence. Only interaction of the target-bound probes can initiate RCA, as free or nonspecifically bound copies of probe 72 remaining when DNA polymerase is added will extend their 3′ ends on themselves (see probe 72 structure), further decreasing the probability of generating false signals. Thus, although our preferred method includes a washing step to remove unbound interacting probes prior to addition of amplification reagents, such a washing step can be eliminated. RCA product AP is detected as described above in connection with
Some aspects of the lengths and sequences of various elements in the hairpin probes of this invention are relatively flexible, whereas the other aspects are relatively constrained.
The loop sequence of an arm-donating probe is designed to be complementary to the intended target sequence (which in some embodiments includes multiple allelic variations and in other embodiments excludes all but one variation) but not to other non-target sequences that may be present in a sample. The loop is designed to be sufficiently long to ensure the required uniqueness. The donating arm must include a number of nucleotides sufficient to maintain its hairpin configuration when free in solution or bound non-specifically. Further, whether mismatch-tolerant or allele-specific, its stem must open (dissociate) when the loop binds to its intended target sequence but not if it binds non-specifically. This is the well-known molecular beacon probe construction that is within the skill in the art. When the arm-donating probe's hairpin is to be allele-discriminating, the length of its loop is constrained by the need to reject allelic variations, particularly a single-nucleotide variation (SNV), so it is usually in the range of 10 to 25 nucleotides long. In the Examples below, the loop length/stem length combinations were, in nucleotides, 15/6, 12/6, 11/6, 9/6 (unsatisfactory), and 20/11 for HCR. Example 6 describes a combination of 25/5 for RCA. The donating arm of an arm-donating probe must interact with one stem arm of the arm-acceptor probe to form a hybrid that is stronger than the stem of the arm-donating probe, so that the donating arm will interact relatively irreversibly. The donating arm includes a single-stranded extension of several nucleotides to accomplish that requirement. In the Examples below the lengths of donating-arm extensions were, in nucleotides, 12, 17, and 18.
For embodiments that include HCR signal amplification, the lengths and sequences of the loop and the stem of an arm-acceptor probe are dictated by the choice of HCR monomers, as, when freed by interaction of the probes, the loop and one stem arm comprise an HCR initiator sequence. Analogously, for embodiments that include RCA signal amplification, the lengths and sequences of the loop and the stem of an arm-acceptor probe are dictated by the choice of the circular template. An arm-acceptor probe must maintain its hairpin configuration when free in solution, and it must not open when the probe hybridizes, either correctly to its target sequence or non-specifically. As compared to an arm-donating probe, its loop is generally shorter, and its stem is generally longer. In the Examples below, the loop length/stem length combinations of arm-acceptor probes were, in nucleotides, 8/18 for HCR. Example 6 describes a combination of 6/20 for RCA. One arm of the hairpin of an arm-acceptor probe has, in addition to stem-forming nucleotides, a single-stranded extension that includes a target-complementary sequence and, in certain embodiments, also a toehold sequence that is complementary to the stem-forming sequence of the donating arm of the arm-donating probe. The length of target-complementary segment can vary a great deal, for example from 15 to 50 nucleotides. In the Examples below, the target-complementary segments of the arm-acceptor probes were, in nucleotides, 19, 20, 22 or 24 for HCR. Example 6 describes a length of 22 nucleotides for RCA.
The length of the toehold sequence (and its complement in the arm-donating probe) has a significant impact on the specificity of allele discrimination: the shorter the toehold sequence, the more discriminatory the probes are. Arm-acceptor probes with toehold sequences 3 to 11 nucleotides long function well as general target detection probes. However, in allele-discriminating embodiments, better allele discrimination is achieved with smaller toehold sequences, with, as we have discovered, the best allele discrimination being exhibited by a toehold sequence of 0 nucleotides. In the Examples below, the lengths of the single-stranded extensions were, in nucleotides, 0-nt toehold plus 19, 20 or 22 target-complementary nucleotides; 5-nt toehold/plus 22 target-complementary nucleotides; and 14-nt toehold plus 24 target-complementary nucleotides for HCR initiation. Described for RCA initiation is an arm-acceptor probe whose single-stranded extension includes 22 target-complementary nucleotides and additionally a toehold sequence 5-nt long.
When there is a toehold sequence, the stem-portion of the arm-donating probe is complementary to the arm-acceptor probe's toehold sequence. In the first probe pair described in Example 3, the toehold sequence in the arm-acceptor probe was 5-nt long but the stem of the arm-donating probe was 6-nt long. To accommodate that difference, the single-stranded extension was reduced from 18 nucleotides (fully complementary to the 18-nt long stem arm of the arm-acceptor probe) to 17 nucleotides, with the terminal nucleotide of arm-donating probe's stem contributing the 18th nucleotide. So stem-forming sequence of the 5′ arm is complementary to the toehold sequence, as required, but it is one nucleotide longer, and the single-stranded extension is complementary to, but one nucleotide shorter than, its complement in the arm-acceptor probe. When there is no toehold sequence, the donating arm of the beacon probe, comprising stem-forming nucleotides and a single-stranded extension, is the same length as the stem of the arm-acceptor probe.
One part of each probe in a pair of interacting hairpin probes is specific to a target sequence and the other part of each probe is generic and can be used with different probe pairs for many different target sequences. With reference to
Special adjustments in hybridization procedures are needed for the detection of DNA targets with the probes of this invention. Because cellular DNA is double stranded, it is not readily accessible to probes for hybridization. To make such DNA target sequences accessible, fixed and permeabilized cells are subjected to a heat treatment in the presence of a denaturant (Vargas et al (2005) Proc. Natl. Acad. Sci. USA 102: 17008-17013). For example, incubating cells in presence of 2×SSC and 70% formamide at 80° C. for 10 minutes denatures genomic DNA sufficiently to permit subsequent hybridization with oligonucleotide probes, including interacting probe pairs of this invention, under normal conditions. In addition, so that any RNA species that is transcribed from the DNA target and is present in the cell will not obscure fluorescent signals from the DNA target, the cellular RNAs can be removed before interacting hairpin probes are added by a prior treatment with ribonuclease A. Typically a non-repeated nuclear DNA target sequence will be present only in two copies (one on each chromosome) in a given cell nucleus. Therefore, only two spots are generated by each set of interacting hairpin probes, and they are located within the nucleus. An additional consideration for the detection of DNA targets is that since DNA/DNA hybrids are slightly less stable than RNA/DNA hybrids formed between an interacting DNA hairpin probe pair and an RNA target sequence, the target-complementary segments of a probe pair are generally relatively longer if the target sequence is DNA.
Example 1 compares the level of target sequence-specific signal and the level of background signal obtained when detection of an RNA target sequence and HCR amplification in fixed, permeabilized cells was initiated with a single pair of interacting DNA hairpin probes according to this invention or obtained when HCR was initiated with a single passively tagged DNA hybridization probe of the type shown in
We also analyzed the average number of spots in the cells of each of the four categories (transfected cells/passively tagged probe; transfected cells/interacting hairpin probe pair; untransfected cells/passively tagged probe; and untransfected cells/interacting hairpin probe pair) by computational image analysis (Raj et al (2008)). We found that on average HeLa cells expressing GFP yielded more than 100 spots/cell with both kinds of probes (the average number of spots could not be determined more precisely, because in many cells the spots were so numerous that they merged with each other, and thus the algorithm could not resolve them from one other). On the other hand, in control cells that did not express GFP the passively tagged probe yielded 1.46 spots per/cell, whereas, the interacting hairpin probe pair yielded 0.62 spots per cell. Just as in the representative images in
To shed additional light on the background and on the specific signals generated by the two probe systems, we analyzed cells by flow cytometry from parallel hybridization-and-amplification reactions performed on cell suspensions. This analysis is presented in
Both image-based and flow-cytometry-based analyses indicate that interactive hairpin probe pairs generate less background signal then do passively tagged probes. On the other hand, the levels of specific signals are about the same in both kinds of probes. Relatively high levels of background signals with passively tagged probes are consistent with the observations of the other laboratories discussed above.
Example 2, part A describes experiments for either of two target-sequence variants that differ by a single nucleotide change using the type of system depicted schematically in
In Example 2, part B, we extended the experimentation of part A to samples containing one of four target-sequence variants; that is A, T, C or G. Against each target-sequence variant we used all six different combinations of two different arm-donating hairpin probes having loops perfectly complementary to one of the target-sequence variants. Detection assays and probes/HCR monomer systems were as described in part A. Each of the six probe mixtures was tested with each of the four target-sequence variants. As this series of experiments was designed, for each target-sequence variant three probe combinations should not yield a significant signal, because neither of the discriminatory arm-donating hairpin probes was perfectly complementary to the target-sequence variant; but three probe combinations should yield a significant signal, because one arm-donating hairpin probe was perfectly complementary to the target-sequence variant. An arm-donating probe that is perfectly complementary to the target sequence that is present should initiate HCR polymerization of the HCR monomer pair for which it was designed (either Cy5-labeled H3 and H4 or TMR-labeled H1 and H2) and yield a fluorescent signal of the appropriate color, while the other arm-donating probe in the mixture should only rarely initiate HCR polymerization by the other HCR monomer pair and yield only a minimum signal of their color. The results of Example 2B showed that that is exactly what occurred. First, assays in which neither arm-donating hairpin probe was complementary to the target-sequence variant did not yield significant fluorescent signal, an average total of 18 spots by microscopic analysis. No bar graphs are presented for these assays. On the other hand, assays in which one arm-donating hairpin probe was complementary to the target-sequence variant did yield significant signal, an average of 91 spots per cell.
Example 3 describes experiments regarding optimization of the structure of a pair of interacting hairpin probes to maximize their of the ability to discriminate between two closely related alleles, namely, a perfectly complementary target sequence and a sequence differing by a single nucleotide substitution, in a detection assay with HCR signal amplification. Key features of the interacting hairpin probes that impact their allele-discriminating ability are (a) the length of the loop of the arm-donating hairpin probe and (b) whether it contains a toehold-complementary sequence complementary to a single-stranded toehold sequence in the arm-acceptor hairpin probe for initiation of strand displacement (see
Example 4 demonstrates the ability to utilize a generic sequence to construct a probe of an interacting hairpin probe pair according to this invention. We chose arm-acceptor probe RA6.3 that was used in Example 1 and has the segments of probe 60 in
Example 5 demonstrates that in addition to mRNAs, other kinds of RNAs can also be detected using the interacting hairpin probes. In the experiment reported in Example 5, we targeted a small guide RNA. Small guide RNAs are used to guide the gene-editing tool Cas-9 (for Clustered regularly interspaced short palindromic repeats assisted endonuclease 9), to its target location within the genome (Cong et al. (2013) Science, 339: 819-823). Small guide RNAs have two functional elements: a portion that binds to the Cas-9 protein and a guide portion that is complementary to a target sequence within the genome. The target-sequence complementary element guides the resulting Cas-9 complex to its complementary genomic site where Cas-9 cleaves the DNA, which leads to the loss of the target gene. Example 5 describes a pair of interacting hairpin probes that target the Cas-9 guide sequence in HeLa cells engineered to express the RNA guide sequence and, when hybridized adjacently, initiate HCR signal amplification. Because the engineered guide RNA was under the control of a U6 promoter, it was expected to be localized in the nuclei of the engineered cells (Lee et al (2008) RNA 14:1823-1833). That differs from mRNAs, which are localized in the cytoplasm of cells.
Example 6 describes a method according to this invention utilizing rolling circle amplification (RCA) rather than HCR for signal amplification. Referring first to
Example 6 describes a pair of interacting hairpin probes RDB RCA and RA RCA that hybridize adjacently on a nucleic-acid target sequence in fixed and permeabilized cells. Once hybridized, they interact to generate an initiator sequence, which in this case is RCA initiator I5. Addition of a circular template and a DNA polymerase leads to RCA signal amplification and detection as described in connection with
Example 7 compares the level of target sequence-specific signal and the level of background signal from flow cytometric detection of interferon gamma (IFNγ) mRNA expressed by stimulated human primary blood mononuclear cells (PBMCs) using three types of probing: a large number of short probes, all singly labeled with the same fluorophore; HCR using a large number of passively tagged probes; and HCR using half as many interacting hairpin probe pairs. PBMCs do not express IFNγ mRNA in their resting state, but when stimulated with phorbol 12-myristate 13-acetate (PMA) and ionomycin, about 15% of them respond by synthesizing IFNγ mRNA (Bushkin et al. (2015) Journal of Immunology 194: 836-841). Since the majority of cells do not express any IFNγ mRNA, this system allows for assessment of signal and background levels from the same cell populations. It will be appreciated that it is particularly important to achieve low levels of backgrounds in flow cytometry-based analyses of intracellular RNAs, because in flow cytometry only the integrated fluorescence from each cell is recorded, and unlike in microscopy, spots detection cannot be used as an aid to distinguish between specific signals and background signals.
In the tests of Example 7, fixed and permeabilized PBMCs and stimulated PBMCs were analyzed by flow cytometry following hybridization of three different types of probes and, for two probe types, HCR signal amplification. A first test of PBMCs and stimulated PBMCs included hybridization of 48 short (20-24 nucleotides long) random-coil DNA probes, each perfectly complementary to the IFNγ mRNA target sequence and labeled at its 3′ end (directly labeled) with a single Cy5 fluorophore. A second test included hybridization of 48 probes having the same target-complementary sequences as in the first test, each having a 31-nucleotide long HCR initiator sequence as a 3′ extension, with HCR amplification of Cy5-labeled HCR hairpin oligonucleotides H3 and H4 (Example 1). A third test included hybridization of 23 pairs of interacting hairpin probes, each pair having the same target-complementary sequences as successive probes in the first test, with HCR amplification of Cy5-labeled HCR hairpin monomers H3 and H4.
The results of the flow cytometry analysis are presented in
The results shown in
Comparison of
Example 8 demonstrates the ability of HCR with interacting hairpin probes of this invention to detect point mutations. For this demonstration we chose mutation L858R in the epidermal growth factor receptor (EGFR) mRNAs in cancer cell lines. Some EGFR mutations render the cancer susceptible to drugs that bind to EGFR, whereas other EGFR mutations in this gene render the cancer impervious to those drugs (Sharma et al. (2007) Nature Review Cancer 11:169-181). Our chosen somatic mutation L858R changes a single wild-type thymidine (T) residue to a mutant guanosine (G) residue at position 2573 of EGFR mRNA (cDNA sequence shown in Example 8) and indicates that tyrosine kinase inhibitors (TKIs) such as erlotinib and gefitinib will be effective against the cancer. For FISH with microscopic detection we selected two cells lines, H1975, which is derived from a non-small cell lung cancer and is known to harbor this mutation in one of the two copies of its EGFR gene (heterozygote); and HeLa cell line that does not contain this mutation and is thus wild-type with respect to this mutation (Kawahara et al Clinical Cancer Research (2010) 16:3163-3170). A mutant homozygote cell line is not available for this mutation.
For probing and initiation of HCR signal amplification we added to the fixed and permeabilized cells both interacting probe pairs of the four-probe system depicted in
In order to demonstrate that the spots generated by interacting hairpin probe pairs generally stem from EGFR mRNAs, we simultaneously hybridized (with the two pairs of interacting hairpin probes) a set of 48 short random-coil DNA probes, each perfectly complementary to both the wild-type and mutant target sequence and labeled at its 3′ end (directly labeled) with a single Texas Red fluorophore. These probes will bind to both kinds of targets and will produce signal in the Texas Red channel. They were employed as “tracer” or “marker” probes to confirm that the HCR signals were arising from the intended targets. It was expected that virtually all mRNA molecules in the cell would be detected in the Texas Red channel (Raj et al. (2008) Nature Methods 5:877-879). Specific HCR signals that emanate from EGFR mRNAs were expected to co-localize with these Texas Red signals, whereas, non-specific HCR signals were not expected to co-localize with the Texas Red signals.
Example 8 reports two experiments. In a first experiment we used a one-step hybridization reaction wherein the hybridization reaction mixture (50 μl) contained the set of short directly labeled probes, 5 ng of each arm-donating hairpin probe, and 5 ng of each acceptor hairpin probe. For a second experiment we made two changes: we performed probe hybridization in two-steps separated by washing. The reaction mixture for the first hybridization contained the acceptor probes but not the arm-donating probes, and the reaction mixture for the second hybridization contained the arm-donating hairpin probes but not the acceptor probes. For the second experiment the amount of each arm-donating hairpin probe was increased from 5 ng to 20 ng. We note that the hairpin sequences, reaction-mixture concentrations, and procedures of the foregoing experiments, although sufficient for this demonstration, were not optimized. Additionally, we did not ascertain the relative expression levels of the two alleles, which may well be imbalanced (Milani et al. (2017) Allelic imbalance in gene expression as a guide to cis-acting regulatory single nucleotide polymorphisms in cancer cells, Nucleic Acids Research 35:e34).
Images and image analyses are presented from one cell each of H1975 and HeLa cell lines in
In the first experiment using one-step hybridization of interacting hairpin probes, we found that on average, the H1975 cells express 42.5 molecules of EGFR mRNAs, whereas, the HeLa cells produce 18.3 molecules of this mRNA. In H1975 cells the interacting hairpin probes were able to detect 34% of the targets, whereas, in HeLa cells they are able to detect 20% of the targets. In the heterozygote cell line H1975, the probes produced signals that indicate that 66% of the detected mRNA molecules (100*((9.4/(9.4+4.9))) were mutant and the rest are wild-type, whereas in the wild-type cell line HeLa, 92% of the molecules (100*(3.3/(3.4+0.2))) were found to be wild-type and rest being the mutant. This analysis, which relies on Texas Red signals as guides, points to the exquisite specificity of the probes towards the mutation. The results of the first experiment also show that a number of spots in both TMR and Cy5 channels do not co-localize with Texas Red spots. Since these spots arise from potentially non-specific sources, and decrease the sensitivity of assays, we sought to decrease their number by performing two-step hybridization.
Comparison of TMR “Alone” and Cy5 “Alone” spots in the last two rows versus the middle two rows indicates that changing from one-step to two-step probe hybridization decreased the average number of non-co-localized spots significantly, while the specific spots (those that were co-localized with Texas red) remained about the same or increased slightly. Thus, the distinction between heterozygote and wild-type became even more accurate and reliable than it was with one-step hybridization. This distinction can be made without the knowledge of co-localization with the set of short, directly labeled probes as tracers.
The results of the two experiments suggest that mutant L858R mRNA targets are detected with higher efficiency than the wild-type targets. In one-step hybridization (60 cells) of H1975: 44% of the MUT mRNAs were detected (9.4/21.2), and 23% of the WT mRNAs were detected (4.9/21.2), whereas, in the two-step hybridization (50 cells) of H1075: 47% of the MUT mRNAs were detected (12.9/27.3), and 13% of the WT mRNAs were detected (3.6/27.3). The numerators in these calculations represent the number of spots in TMR and Cy5 channels that were co-localized with Texas Red and the denominators represent the half of total Texas Red mRNA molecules (Table 2). The lower efficiency of detection of the wild-type mRNA was also apparent in the wild-type cells line HeLa. In this case in one-step hybridization (60 cells) of HeLa: 19% of the WT mRNAs were detected (3.4/18.3), and (erroneously) only 1% responded to the mutant probe (0.2/18.3). Similarly, in the two-step hybridization (50 cells) of HeLa: 17% of the WT mRNAs were detected (3.4/20.1), and (erroneously) only 2% responded to the mutant probe (0.5/20.1). The denominators in these calculations are total Texas Red labeled mRNA molecules.
While it is possible that these differences result from an imbalance in the expression of two alleles due to an allelic imbalance, (Milani et al. 2017), another cause could be differential accessibility of the mRNA of two alleles to probes. A simple method of addressing this in order to optimize the assay is to separately normalize the number of spots for each allele. A second approach would be to “fine tune” the concentrations of the two probes, that is, increasing the concentration of the left donating beacon probe (WT) and decreasing the concentration of the right donating beacon probe (MUT), so that overall efficiency of the detection of the two mRNAs is about equal. Yet another approach would be to modify the structure of the left arm-donating probe or the left acceptor probe, or both, to increase the efficiency of initiator generation.
In order to demonstrate the ability of interacting hairpin probe pairs to generate amplified signals specifically from intended mRNA target sequences, we expressed a heterologous mRNA encoding green fluorescent protein (GFP) in HeLa cells. GFP is normally not present in these cells. This mRNA served as the target of our probes. This system allowed us to assess target-specific signals from the cells that express the GFP mRNA and to assess background signals from HeLa cells that do not express GFP mRNA.
GFP target sequence
(SEQ ID NO. 1)
5'-UCGUGACCACCCUGACCUACGGCGUGCAGUGCUUCAG
CCGCUACCCCGAC-3'
HCR hairpin oligonucleotide H3
(SEQ ID No. 2)
5'-Cy5-ACAGACGACTCCCACATTCTCCAGGTGGGAGTCGTCTGT
AACATGAAGTA-3'
HCR hairpin oligonucleotide H4
(SEQ ID No. 3)
5'-CTGGAGAATGTGGGAGTCGTCTGT
TACTTCATGTTACAGACGACTCCCAC-Cy5-3'
Passively tagged probe
(SEQ ID No. 4)
5'-GTCGGGGTAGCGGCTGAAGAAAAATACTTCATGTTACAGA
CGACTCCCAC-3'
Arm-Donating Hairpin Probe (RDB6.6)
(SEQ ID No. 5)
5'-GTTACAGACGACTCCCACCACTGCACGCCGTGGGA-3'
Arm-Acceptor Hairpin Probe (RA6.3)
(SEQ ID No. 6)
5'-GTCGGGGTAGCGGCTGAAGGTGGGAGTCGTCTGTAACTAC
TTCATGTTACAGACGACTCCCAC-3'
In the foregoing sequences, stem-forming complementary segments are underlined.
For these sets of experiments we either used a passively tagged hybridization probe against GFP mRNA analogous to the probe of Choi et al (2014), or we used a pair interacting hairpin hybridization probes according to this invention, first interacting hairpin probe RDB6.6 that contains a target-complementary sequence, and second interacting hairpin probe RA6.3. The passively tagged probe was designed such that its target-complementary segment (or probe sequence) is the same as the target-complementary sequence (or probe sequence) in the second interacting hairpin probe RA6.3, the arm-acceptor probe. In this passively tagged probe, the target-complementary sequence (or probe sequence or probing sequence) at the 5′ end is followed (towards its 3′ end) by a spacer of 5 nucleotides (AAAAA) and then by an HCR initiator sequence I3, comprising sequences g′,f′-3′, which is an initiator for HCR hairpins H3 and H4. All oligonucleotides were obtained from Integrated DNA Technologies (IDT) (Coraville, Iowa, U.S.A.). HCR hairpin H3 was obtained with a 5′ terminal amino label, and HCR hairpin H4 was obtained with a 3′ terminal amino label. Oligonucleotides possessing amino labels were conjugated to Cy5 succinimidyl ester and then purified by HPLC as described before (Tyagi and Kramer (1996)). These labeled HCR hairpin monomers and the probes were further purified using denaturing polyacrylamide gel electrophoresis on a 10% polyacrylamide gel containing 8 M urea, resuspended in water, and quantified using a Nanodrop spectrophotometer. In order to ensure that the probes and the hairpin monomers were properly folded before use, the probes were diluted to 5 ng/μl and the HCR hairpin monomers were diluted to 25 nM in 2×SSC (about 100 μl solution), heated in boiling water for 2 minutes, and then allowed to cool at room temperature for 10 minutes.
The DNA template of this mRNA (plasmid pTREd2EGFP, Clontech) was transfected into HeLa cells using a standard protocol (Vargas et al. (2005)). The cells that were transfected (received the plasmid) became fluorescent due to the expression of GFP. Thereafter, the cells were detached from plastic dishes and transferred to glass coverslips where they were cultured for another day. These cells were fixed with 4% formaldehyde in 1× phosphate buffered saline (PBS), permeabilized with 70% ethanol, equilibrated with 10% formamide in 2λ saline sodium citrate (SSC) buffer (Ambion, Austin, Tex.) (probe wash buffer).
The passively tagged probe or the interacting probe pair was then added to the fixed and permeabilized cell, and the resulting mixture was incubated overnight in a humid chamber at 37° C. to hybridize the probes to the target sequence and to permit the probe-probe interactions. The hybridization reaction mixture (50 μl) contained 5 ng of each probe and 10% dextran sulfate (Sigma), 1 mg/ml Escherichia coli tRNA (Sigma), 2 mM ribonucleosidevanadyl complex (New England Biolabs, Ipswich, Mass.), 0.02% RNase-free bovine serum albumin (Ambion), 10% formamide and 2×SSC. After hybridization and interaction of the probe pair, the coverslips were washed twice with 1 ml of the probe wash buffer to remove unhybridized probes. Each wash was carried out at room temperature for 10 minutes. Finally, the cells were equilibrated with 50 mM Na2HPO4, 1 M NaCl, 0.05% (v/v) Tween-20, pH 7.4 (HCR buffer).
After removal of excess probes, HCR was performed in a 50 μl reaction for 4 hours at 37° C. in the humid chamber. The HCR reaction mixture contained 25 nM of each of HCR hairpin oligonucleotides H3 and H4, described earlier by Koss et al (2015) (Nature Communications 6:7294) dissolved in HCR buffer. HCR hairpin monomers were labeled with Cy5. After HCR amplification, excess (unused) HCR hairpin oligonucleotides were removed by washing in HCR buffer in the same manner as done for probe removal above. For both of the incubation steps (hybridization and HCR) a parafilm sheet was placed on a glass plate, the droplets of the reaction buffer were placed on the parafilm sheet and then coverslips were placed on the droplets with the side to which the cells are attached facing down. The coverslips were mounted and imaged as described earlier (Raj et al (2008)).
In a parallel experiment, aimed at analyzing signals by flow cytometry, cells were cultured on plastic dishes for one day after transfection and then detached. The detached cells were suspended in PBS, fixed and permeabilized. The probe pair was added and incubated for hybridization and interaction, followed by washing to remove unbound probes, performing HCR amplification, and washing again using the HCR buffer. However, since the cells were in suspension rather than attached to the coverslips, for each incubation/wash cycle, they were spun briefly in a centrifuge using a swinging tube rotor, and the supernatant was removed by aspiration and replaced by the fresh solution. After the final wash, these cells were suspended in the probe wash buffer and analyzed on a Becton Dickinson Accuri 6C Flow Cytometer in the fluorescein channel (for GFP) and in the Cy5 channel (for HCR products).
The coverslips were imaged with a 60× objective with a Nikon Eclipse Ti microscope in the DAPI, DIC, fluorescein (or GFP) and Cy5 channels. The first two channels enabled the identification of cells and their boundaries, the fluorescein channel enabled the identification of transfected cells, and the Cy5 channel was used for recording of the probe signals. Eleven optical sections were obtained for the Cy5 channel. The HCR-amplified signals appear as discrete spots. The spots within cell boundaries were counted using a previously described algorithm (Raj et al (2008)). Representative images are presented in
In order to demonstrate the utility of interacting hairpin probes for the detection of single-nucleotide variations of a target sequence, we created four single-nucleotide variants of the GFP coding sequence by mutating the wild-type d2EGFP sequence (Clontech) using a site-directed mutagenesis procedure (Change-IT, Affymetrix) at a particular location so that none of the changes would negatively impact its fluorescence. We substituted either, an adenosine, a cytosine, or a thymidine for the guanosine that is normally present at position 207 of the d2EGFP coding sequence. The sequence context of the nucleotide that was changed (underlined) is CCTACGGCGTGCAGTGCTTC (SEQ ID NO: 47). The plasmids encoding these four GFP variants were separately transfected into HeLa cells as described in Example 1. It was confirmed that each variant of yielded GFP-fluorescent cells.
The sequences of the oligonucleotides in this example:
GFP target sequence variants
(SEQ ID NO. 1)
(G variant) 5'-UCGUGACCACCCUGACCUACGGCGUGCAGUG
CUUCAGCCGCUACCCCGAC-3'
(C variant)
(SEQ ID No. 7)
5'-UCGUGACCACCCUGACCUACGGCGUCCAGUG
CUUCAGCCGCUACCCCGAC-3'
(A variant)
(SEQ ID No. 8)
5'-UCGUGACCACCCUGACCUACGGCGUACAGUG
CUUCAGCCGCUACCCCGAC-3'
(T variant)
(SEQ ID No. 9)
5'-UCGUGACCACCCUGACCUACGGCGUTCAGUG
CUUCAGCCGCUACCCCGAC-3'
Right arm-donating hairpin probe variants
C variant RDB6.6C
(SEQ ID No. 5)
5'-GTTACAGACGACTCCCACCACTGCACGCCGTGGGA-3'
T variant RDB6.6T
(SEQ ID No. 10)
5'-GTTACAGACGACTCCCACCACTGTACGCCGTGGGA-3'
A variant RDB6.6A
(SEQ ID No. 11)
5'-GTTACAGACGACTCCCACCACTGAACGCCGTGGGA-3'
G variant RDB6.6G
(SEQ ID No. 12)
5'-GTTACAGACGACTCCCACCACTGGACGCCGTGGGA-3'
Right arm-acceptor hairpin probe RA6.3
(SEQ ID No. 6)
5'-GTCGGGGTAGCGGCTGAAGGTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
HCR hairpin oligonucleotide H3
(SEQ ID No 2)
5'-Cy5-ACAGACGACTCCCACATTCTCCAGGTGGGAGTCGTCTGT
AACATGAAGTA-3'
HCR hairpin oligonucleotide H4
(SEQ ID No. 3)
5'-CTGGAGAATGTGGGAGTCGTCTGTTACTTCATGTTACAGACGAC
TCCCAC-Cy5 -3'
Left arm-donating hairpin probe variants
T_variant LDB6.1T
(SEQ ID No. 13)
5'-ACGAGGCACTGTACGCCCCTCGTAAATCCTCATCAATCATC-3'
C variant LDB6.1C
(SEQ ID No. 14)
5'-ACGAGGCACTGCACGCCCCTCGTAAATCCTCATCAATCATC-3'
A variant LDB6.1A
(SEQ ID No. 15)
5'-ACGAGGCACTGAACGCCCCTCGTAAATCCTCATCAATCATC-3'
G variant LDB6.1G
(SEQ ID No. 16)
5'-ACGAGGCACTGGACGCCCCTCGTAAATCCTCATCAATCATC-3'
Left arm-acceptor hairpin probe LA6.1
(SEQ ID No. 17)
5'-CCTCGTAAATCCTCATCAATCATCCAGTAAACCGCCGATGATTGA
TGAGGATTTACGAGG GTAGGTCAGGGTGGTCACGA-3'
HCR hairpin oligonucleotide H1
(SEQ ID No. 18)
5'-GGCGGTTTACTGGATGATTGATGAGGATTTACGAGGAGCTCAGT
CCATCCTCGTAAATCCTCATCAATCATC-TMR-3'
HCR hairpin oligonucleotide H2
(SEQ ID No. 19)
5'-TMR-CCTCGTAAATCCTCATCAATCATCCAGTAAACCGCCGATGA
TTGATGAGGATTTACGAGGATGGACTGAGCT-3'
In the wild-type GFP target sequence and arm-donating probes, the variable nucleotide is bolded. Underlined sequence segments indicate arms of hairpin stems.
A. Probing Either of Two Target Variants with Two Interacting Probe Pairs
We first separately probed cells expressing the G variant (wild-type) and cells expressing the A variant of GFP mRNA with a set of two interacting hairpin probe pairs (four probes consisting of RA6.3, LA6.1, RDB6.6C, whose loop sequence is complementary to the G target-sequence variant, and LDB6.1T, whose loop is complementary to the A target sequence variant). Utilizing this probe set, if arm-donating probe RDB6.6C binds such that its stem opens, its donating arm can then interact with arm-acceptor probe RA6.3, freeing its HCR initiator sequence, which can then initiate HCR amplification of Cy5-labeled hairpin oligonucleotides H3 and H4, yielding a Cy5 signal. However, if instead arm-donating probe LDB6.1T binds such that its stem opens, its donating arm can to it then interact with arm-acceptor probe LA6.1, freeing its HCR initiator sequence, which can then initiate HCR amplification of TMR-labeled HCR hairpin oligonucleotides H1 and H2, yielding a tetramethylrhodaimine (TMR) signal.
The cells and the probes were prepared, and the hybridization-interaction incubation of each sample (G variant or A variant) was performed as in Example 1 using all four probes in each case. After removal of excess probes by washing as described in Example 1, HCR amplification was performed on each sample as described in Example 1, during which two sets of HCR hairpins Cy5-labeled H3 and H4, and TMR-labeled H1 and H2 were present. After removing excess (unused) HCR hairpin oligonucleotides, the coverslips were imaged with a 100× objective in a Zeiss Axiovert microscope in DAPI, DIC, TMR and Cy5 channels. Representative images obtained from the TMR and the Cy5 channels are presented for both samples in
B. Probing Other Target Variants with Two Interacting Probe Pairs
We repeated Example 2A for all four variants of the GFP mRNA target sequence. We tested a sample with each target-sequence variant using six different probe mixtures, which differed in their six combination of two arm-donating hairpin probes. All assays included acceptor probes LA6.1 and RA6.3, as well as HCR hairpin oligonucleotides H1, H2, H3 and H4. The two arm-donating probes for each of the six combinations are identified in Table 1.
TABLE 1
System
Complementary Target-
Left Arm-
Right Arm-
Designation
Sequence Variants
Donating Probe
Donating Probe
GgTr
C and A
LDB6.1G
RDB6.6T
GgAr
C and T
LDB6.1G
RDB6.6A
GgCr
C and G
LDB6.1G
RDB6.6C
TgAr
A and T
LDB6.1T
RDB6.6A
TgCr
A and G
LDB6.1T
RDB6.6C
AgCr
T and G
LDB6.1A
RDB6.6C
In the system designation in Table 1, the capital letters identify, for each of the two arm-donating hairpin probes in the two interacting probe pairs, the loop nucleotide that is opposite the target-sequence variable nucleotide, and the color of the signal resulting from its opening, that is, either green (TMR) or red (Cy5).
Each of the six probe mixtures in Table 1 was tested with each of the four target sequences. For each probe mixture, two target-sequence variants are complementary to one of the two arm-donating probes, and two target-sequence variants are not complementary to either of the arm-donating probes, that is, they are non-cognate target-sequence variants. For example, the probe system designated GgTr included an arm-donating probe, which we call the left arm-donating probe, having a loop complementary to target-sequence variant C and an arm-donating probe, which we call the right arm-donating probe, having a loop sequence complementary to target-sequence variant A, so those two target-sequence variants were the cognate variants, while target-sequence variants G and T were the non-cognate variants. Assays that included non-cognate target-sequence variants did not yield significant fluorescent signals from either the TMR fluorophore resulting from hybridization and opening of the left arm-donating hairpin probe or the Cy5 fluorophore resulting from hybridization and opening of the right arm-donating hairpin probe. Results of assays that included cognate target-sequence variants are presented in
We tested four pairs of interacting hairpin probes in detection assays using cells expressing either one of two target-sequence variants: GFP mRNA (G) (SEQ ID No. 1), that was perfectly complementary to the loop of the arm-donating hairpin probe, or GFP mRNA (A) (SEQ ID No. 8), that was mismatched to the loop of the arm-donating hairpin probe by a single nucleotide. The sequences of the oligonucleotides used in this example were as follows:
GFP target sequence variants
(G variant)
(SEQ ID NO. 1)
5'-UCGUGACCACCCUGACCUACGGCGUGCAGUG
CUUCAGCCGCUACCCCGAC-3'
(A variant)
(SEQ ID No. 8)
5'-UCGUGACCACCCUGACCUACGGCGUACAGUG
CUUCAGCCGCUACCCCGAC-3'
First probe pair
Arm-Donating Hairpin Probe RDB6.3
(SEQ ID No. 20)
5'-GTTACAGACGACTCCCA
CAGTCCAGCACTGCACGCCGTGGACTG-3'
Arm-Acceptor Hairpin Probe RA6.2
(SEQ ID No. 21)
5'-ATGTGGTCGGGGTAGCGGCTGAGGACT GTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
Second probe pair
Arm-Donating Hairpin Probe RDB6.1
(SEQ ID No. 22)
5'-GTTACAGACGACTCCCACAGCACTGCACGCCGTGTGGGA-3'
Arm-Acceptor Hairpin Probe RA6.0
(SEQ ID No. 23)
5'-ATGTGGTCGGGGTAGCGGCTGA GTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
Third probe pair
Arm-Donating Hairpin Probe RDB6.5
(SEQ ID No. 24)
5'-GTTACAGACGACTCCCACAGCACTGCACGCGTGGGA-3'
ARM-Acceptor Hairpin Probe RA6.0
(SEQ ID No. 23)
5'-ATGTGGTCGGGGTAGCGGCTGAGTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
Fourth probe pair
ARM-Donating Hairpin Probe RDB6.7
(SEQ ID No. 25)
5'-GTTACAGACGACTCCCACACTGCACGCGTGGGA-3'
ARM-Acceptor Hairpin Probe RA6.0
(SEQ ID No. 23)
5'-ATGTGGTCGGGGTAGCGGCTGAGTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
HCR hairpin oligonucleotide H3
(SEQ ID No. 2)
5'-Cy5-ACAGACGACTCCCACATTCTCCAGGTGGGAGTCGTCTGT
AACATGAAGTA-3'
HCR hairpin oligonucleotide H4
(SEQ ID No. 3)
5'-CTGGAGAATGTGGGAGTCGTCTGT
TACTTCATGTTACAGACGACTCCCAC-Cy5-3'
In the foregoing sequences the hairpin arm sequences are underlined.
In the first pair of probes, arm-donating hairpin probe RDB6.3 contained a 15-nt long loop sequence, and it contained a 5-nt long toehold-complementary sequence. Its interacting probe, arm-acceptor hairpin probe RA6.2 contained a 5-nt long toehold sequence. Referring to the sequence of probe RA6.2, the 22 nucleotides at the 5′ end are complementary to the target sequence, and the next five nucleotides (GGACT) are the toehold sequence. In the second probe pair arm-donating hairpin probe RDB6.1 contained a 15-nt long loop sequence but no toehold-complementary sequence; and arm-acceptor hairpin probe RA6.0 contained no toehold sequence. In the third probe pair arm-donating hairpin probe RDB6.5 contained a 12-nt long loop sequence but no toehold-complementary sequence; and arm-acceptor probe RA6.0 contained no toehold sequence. Finally, in the fourth probe pair arm-donating hairpin probe RDB6.7 contained a 9-nt long loop sequence but no toehold-complementary sequence; and arm-acceptor probe RA6.0 contained no toehold sequence.
Each HCR detection method utilized, in addition to one of the target-sequence variants and one of the interacting hairpin probe pairs described above, a single pair of HCR hairpin oligonucleotides, H3 and H4. Reactions were carried out as described in Example 2. Results are presented in
In order to investigate the possibility of preparing arm-acceptor probes from a generic hairpin and a target-complementary sequence specific to a particular target, we synthesized a version of arm-acceptor probe RA6.3 using click chemistry and compared its performance to “normal” arm-acceptor probe RA6.3 containing only phosphodiester bonds. Of the two components, the generic acceptor hairpin oligonucleotide was obtained with a 5′ amino group, and the acceptor target-complementary sequence oligonucleotide was obtained with a 3′ amino group. The sequences of the oligonucleotides used in this example were as follows:
Arm-acceptor probe generic hairpin
(SEQ ID No. 26)
5'-Amino-GTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'_
Arm-acceptor probe specific target-complementary
sequence
(SEQ ID No. 27)
5'-GTCGGGGTAGCGGCTGAAG-Amino-3'
Arm-acceptor probe RA6.3
(SEQ ID No. 6)
5'-GTCGGGGTAGCGGCTGAAGGTGGGAGTCGTCTGTAAC
TACTTCATGTTACAGACGACTCCCAC-3'
GFP target sequence
(SEQ ID NO. 1)
5'-UCGUGACCACCCUGACCUACGGCGUGCAGUGCUUCA
GCCGCUACCCCGAC-3'
Arm-donating hairpin probe RDB6.6
(SEQ ID No. 5)
5'-GTTACAGACGACTCCCACCACTGCACGCCGTGGGA-3'
HCR hairpin oligonucleotide H3
(SEQ ID No. 2)
5'-Cy5-ACAGACGACTCCCACATTCTCCAGGTGGGAGTCGTCTGT
AACATGAAGTA-3'
HCR hairpin oligonucleotide H4
(SEQ ID No. 3)
5'-CTGGAGAATGTGGGAGTCGTCTGT
TACTTCATGTTACAGACGACTCCCAC-Cy5-3'
In the foregoing sequences, stem arm sequences are underlined.
The 3′ amino group of the target-complementary sequence oligonucleotide was modified to an azide functionality by using 4-azidobutyrate-N-hydrosuccinimidyl ester (Sigma-Aldrich). Separately, the amino group at the 5′-terminus of the generic acceptor hairpin was conjugated to dibenzocyclooctyne (DBCO) using dibenzocyclooctyne-N-hydroxysuccinimidyl ester (Sigma-Aldrich). Both modified oligonucleotides were purified by high-pressure liquid chromatography. The two oligonucleotides were linked to each other by mixing them in equimolar ratios and incubating them overnight in buffer composed of 50 mM KCl, 2.5 mM MgCl2, and 10 mM Tris-HCl (pH 8.0). We refer to the full-length conjugated oligonucleotide probe as RA6.3-click. It was purified using denaturing polyacrylamide gel electrophoresis using a 12% polyacrylamide gel containing 8 M urea, resuspended in water, and quantified using a Nanodrop spectrophotometer. RA6.3-click was folded into its hairpin conformation by heating and cooling as described earlier. Properly folded arm-acceptor probe RA6.3-click was then used in combination with arm-donating hairpin probe RDB6.6 and HCR monomers H3, H4 in a hybridization assay with HCR signal amplification and microscopic detection to image cells expressing wild-type GFP mRNA target-sequence variant G (SEQ ID No. 1) as described in Example 1. In parallel, we utilized “normal” arm-acceptor probe RA6.3 in the same assay method to image the cells expressing the same GFP mRNA. Representative images shown in
We expressed a guide RNA target sequence against the Cox-2 gene in HeLA cells. This sequence was inserted in plasmid pGL3-U6-sgRNA-PGK-puromycin (Addgene) and the engineered plasmid was transfected into HeLa cells. Following transfection, cells were fixed and permeabilized as described in Example 1.
To detect the Cox-2 guide RNA, we designed a pair of interacting hairpin probes that initiate HCR amplification in the method of Example 1. These probes were prepared and purified as described in Example 1. The sequences of the oligonucleotides used in this example were as follows:
Cox-2 Guide RNA Target Sequence
(SEQ ID No. 28)
5'-CCGGUGUACGUCUUUAGAGGGUCGGUUUUAGAGCUAGAAAUA
GCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUG-3'
Arm-Donating Hairpin Probe for Cox-2
Guide RNA Target Sequence
(SEQ ID No. 29)
5'-GTTACAGACGACTCCCACAGACGAATACA GCG
CGACCCTCTAAAGACGTTGTATTCGTCT-3'
Arm-Acceptor Probe for Cox-2 Guide RNA
Target Sequence
(SEQ ID No. 30)
5'-TTAACTTGCTATTTCTAGCTCTAACGCTGTATTCGTCT
GTGGGAGTCGTCTGTAACTACTTCATGTTACAGACGACTCCCAC-3'
HCR hairpin oligonucleotide H3
(SEQ ID No. 2)
5'-Cy5-ACAGACGACTCCCACATTCTCCAGGTGGGAGTCGTCTGT
AACATGAAGTA-3'
HCR hairpin oligonucleotide H4
(SEQ ID No. 3)
5'-CTGGAGAATGTGGGAGTCGTCTGT
TACTTCATGTTACAGACGACTCCCAC-Cy5-3'
In the foregoing sequences, stem arm sequences are underlined.
Hybridization and interaction of the hairpin probe pair, HCR amplification, and imaging were performed as described in Example 1. Results are presented in
This example describes reagents and a method for use of a pair of interacting hairpin probes to initiate signal amplification by rolling circle amplification (RCA) for detection of a nucleic-acid target sequence by sm-FISH. The target in this example is an array 3 sequence in an engineered GFP gene described earlier by Vargas et al (2011) Cell 147:1054-1065). A Chinese hamster cell line stably expressing a GFP-array3 construct is cultured on glass coverslips and then fixed and permeabilized in the same manner as described in previous Examples for HeLa cells.
The sequences of the oligonucleotides to be used are as follows:
Array 3 target sequence
(SEQ ID No. 31)
5'-UCGACGCGGAGACCACGCUCGGCUUGUCUUUCGCGCGCAAUGC
GACGCACGCGGAUAGUUAGCUGCGGCGACGAGGCACC-3'
Oligonucleotide for circular template
(SEQ ID No. 32)
5'-TTTAAGCGTCTTAACTATTAGCGTCCAGTGAATGCGAGTCCGTC
TAAGAGAGTAGTACAGCAGCCGTCAAGAGTGTCTAGTTCTGTCATA-3'
Splint oligonucleotide for circular template
(SEQ ID No. 33)
5'-TAAGACGCTTAAATATGACAGAACTA-3'
Arm-donating hairpin oligonucleotide, RDB RCA
(SEQ ID No. 34)
5'-GCTTAAATATGACAGAACTAAGTCCGAAAGACAAGCCGAGCGTG
GTCTCCGGACT-3'
Arm-acceptor hairpin oligonucleotide, RA RCA
(SEQ ID No. 35)
5'-CCGCGTGCGTCGCATTGCGCGC GGACT
TAGTTCTGTCATATTTAAGCTAAGACGCTTAAATATGACAGAACTA-3'
Detector Probe for RCA product
(SEQ ID No. 36)
5'-TGCGAGTCCGTCTAAGAGAG-TMR-3'
To create a circular template for RCA a linear oligonucleotide (SEQ ID No. 32) is phosphorylated at its 5′ end using T7 polynucleotide kinase (New England Biolabs, Ipswich, Mass., U.S.A.), annealed to a splint oligonucleotide (SEQ ID No. 33), and then ligated using T4 DNA ligase (New England Biolabs) following manufacturer's instructions. The circularized template DNA is then dissociated from the splint oligonucleotide by denaturation for 10 min at 100° C. in 85% formamide, followed by purification by electrophoresis on a 10% polyacrylamide gel containing 8 M urea. The pair of interacting hairpin probes is purified and prepared was described in Example 1.
The interacting hairpin probe pair, arm-donating hairpin probe RDB RCA and arm-acceptor probe RA RCA, is hybridized to the target sequence in the fixed and permeabilized cells (5 ng of each probe for each 50 μl hybridization reaction), and allowed to interact. Excess (unbound) probes are removed in the manner described in Example 1. The circularized template oligonucleotide (5 ng in 50 μl hybridization reaction mixture) is then added and hybridized for 1 hour at 37° C. Unbound (excess) circularized template is removed by two rounds of washing with probe wash buffer. The sample then is equilibrated with polymerase buffer composed of 50 mM Tris-HCl (pH 7.5), 10 mM MgCl2, 10 mM (NH4)2SO4, 4 mM DTT, 250 ng/μl BSA, 0.05% Tween-20, and 0.25 mM of each of the four nucleotide triphosphates. RCA signal amplification is carried out in 50 μl of the same buffer in presence of 0.125 U/μl phi29 DNA polymerase (New England Biolabs) for 1 hour at 37° C. The coverslips are then transferred to a solution containing a TMR-labeled detector probe (SEQ ID No. 36) for the RCA product (5 ng in 50 μl of probe wash buffer) and incubated in the solution for 30 minutes at 37° C. Excess (unbound) copies of the detector probe are removed by two washes with the probe wash buffer, and the coverslips are mounted for microscopic observation, which is performed as described in Example 1. In this procedure it is important to use a DNA polymerases with high processivity and high strand-displacement ability. In this regard the DNA polymerase bacteriophage ϕ29 (New England Biolabs) is a suitable choice.
A number of variations are possible for steps of the method described above. For example, instead of using a preformed circular template, a linear version of the circular template can be used. In that case, the single-stranded RCA initiator sequence resulting from interaction of the interacting hairpin probes will serve as the splint, and circularization will be achieved by an in-situ ligation step. This will reduce the effort required for oligonucleotide preparation. Furthermore, instead of using a linear detector probe for RCA product detection as described above, which requires the washing steps for removal of the excess detector probe, a homogeneous detection probe, preferably a molecular beacon probe, can be utilized. This will obviate the last washing steps, if desired.
It is more critical to achieve low levels of backgrounds in flow cytometry-based analyses of intracellular RNAs than in microscopy-based analyses, because in flow cytometry only the integrated fluorescence from each cell is recorded, and unlike in microscopy the spots detection cannot be used as an aid to distinguish between specific signals and background signals. To demonstrate that HCR detection with interacting hairpin probes yields higher signals-to-background ratios in flow cytometry than HCR detection with passively tagged probes and detection with directly labeled probes, we detected IFNγ mRNA in primary blood mononuclear cells (PBMCs) with all three probe types. PBMCs do not express IFNγ mRNA in their resting state, but when they are stimulated with phorbol 12-myristate 13-acetate (PMA) and ionomycin, about 15% of them respond by synthesizing IFNγ mRNA (Bushkin et al. (2015) Journal of Immunology 19: 836-841). Since the majority of cells do not express any IFNg mRNA, this system allows for assessment of signal and background levels from the same cell populations.
Probe Sequences and Synthesis
The sequence of IFNγ mRNA, set forth as the corresponding cDNA sequence is shown below:
(SEQ ID No. 37)
##STR00001##
Probe sequences were as follows:
Forty-Eight Short, Directly Labeled Probes
The reverse complements of the underlined and gray-shaded sequences in the IFNγ cDNA sequence above.
Passively Labeled HCR Probes
The same set of sequences were also used for the target complementary regions of the passively tagged HCR probes. However, at their 3′ ends, there was appended the following sequence AAAAATACTTCATGTTACAGACGACTCCCAC (SEQ ID No. 38), which serves as an initiator of HCR.
Twenty-Three Right Arm-Donating Hairpin Probes
Their general sequences were: GTTACAGACGACTCCCACNNN . . . NNNGTGGGA (SEQ ID No. 39), where NNN . . . NNN indicates the reverse complement of one of 23 underlined sequences in the IFNγ cDNA sequence above, where the sequence to the left of NNN . . . NNN, namely, GTTACAGACGACTCCCA (SEQ. ID No. 40) is the right arm of each probe (corresponding to the regions f′ and e′ in
Twenty-Three Right Acceptor Hairpin Probes
Their sequences were the reverse complements of the shaded sequences in the IFNγ cDNA sequence above, excluding the first one, to each of which was appended at its 3′ end the generic arm-acceptor probe hairpin (SEQ ID No. 26) described in Example 4.
A Cy5 fluorophore was conjugated to the 3′ end of each of the short, directly labeled probes. Each right arm-donating hairpin probe was prepared by fully automated DNA synthesis (IDT DNA Inc.). Each right acceptor probe, on the other hand, was prepared by ligating the target specific portion of the probe with the generic right acceptor hairpin by click chemistry. For this we started with a pool of 23 oligonucleotides (having the reverse complements of the shaded sequences in the IFNγ cDNA sequence above, excluding the first and the last ones) each at an equimolar concentration, and then and linked them with the generic arm-acceptor probe hairpin (SEQ ID No. 26) at their 3′-ends as described in Example 4. After their synthesis via click chemistry, the right acceptor probes were purified by polyacrylamide gel electrophoresis as described in Example 4. The right arm-donating hairpin probes and right acceptor probes (each as a pool) were heated to 95° C. for 2 minutes and allowed to cool at room temperature for 10 min in 2×SSC (in separate tubes) to ensure that they had properly formed their respective hairpins.
PBMC's were purified from blood. A portion was not stimulated (“resting”), and a portion was stimulated with PMA and ionomycin. Both unstimulated cells and stimulated cells were fixed with formaldehyde, and permeabilized with alcohol and probed with the set of short, directly labeled probes as described in Bushkin et al (2015) Journal of Immunology 194: 836-841). In a parallel set of hybridization reactions, we also probed the cells with the set of passively tagged HCR probes and with the set of interacting hairpin probes. For each 50 μl hybridization reaction, we used 25 ng of the short, directly labeled probes or, 250 ng of the passively tagged probes or, 250 ng of right donating beacon probe set together with 250 ng of the right acceptor probe set. As discussed earlier, each probe set was composed of equimolar concentrations of multiple probes. After an overnight hybridization at 37° C., cells were washed twice in the probe wash buffer. While the reactions with the short, directly labeled probes were analyzed after this step, the reactions with the passively tagged HCR probes and with interacting hairpin probes were washed with the HCR buffer and subjected to HCR amplification using HCR hairpins H3 and H4 labeled with Cy5 for 2 hr at 37° C. as described in Example 1. After HCR the cells were washed twice with the HCR buffer and once with the probe wash buffer and analyzed. The flow cytometry analysis was performed as described in Example 1.
The results of the flow cytometry analysis are presented in
The cells in the left panels appear in single clusters whose peak fluorescence intensities are represented by the vertical bar on each panel. The values of peak intensity were 920 fluorescence units for the set short, directly labeled probes, 9600 units for the set of passively labeled HCR probes, and 650 for the set of interacting hairpin HCR probes. The stimulated cell in the right panels, on the other hand, diverge into two clusters. The left cluster represents unresponsive cells, and the right cluster represents cells producing IFNγg mRNA and which were thus more fluorescent. The peak fluorescence of the right cluster in each panel is indicated by a vertical bar. The values for those peak intensities were 37,000 arbitrary fluorescence units (a.u.) for the set of short, directly labeled probes, 373,000 units for the set of passively labeled HCR probes, and 66,000 units for the set of interacting hairpin HCR probes.
Cell line H1975 and the HeLa cell line were obtained from ATCC (Manasas, Va.) and cultured according to the supplier's instructions. Cell line H1075 harbors somatic mutation L858R in one of the two copies of the EFGR gene (heterozygote), while the HeLa cell line does not contain that mutation. The mutation changes a thymidine (T) residue to a guanosine (G) residue at position 2573 of EGFR mRNA.
Probe Sequences and Synthesis
The sequence of EGFR mRNA, set forth as the corresponding cDNA sequence, is shown below:
(SEQ ID No. 42)
ATGCGACCCTCCGGGACGGCCGGGGCAGCGCTCCTGGCGCTGCTGGCTGCGCTCT
GCCCGGCGAGTCGGGCTCTGGAGGAAAAGAAAGTTTGCCAAGGCACGAGTAACA
AGCTCACGCAGTTGGGCACTTTTGAAGATCATTTTCTCAGCCTCCAGAGGATGTT
CAATAACTGTGAGGTGGTCCTTGGGAATTTGGAAATTACCTATGTGCAGAGGAAT
TATGATCTTTCCTTCTTAAAGACCATCCAGGAGGTGGCTGGTTATGTCCTCATTGC
CCTCAACACAGTGGAGCGAATTCCTTTGGAAAACCTGCAGATCATCAGAGGAAA
TATGTACTACGAAAATTCCTATGCCTTAGCAGTCTTATCTAACTATGATGCAAAT
AAAACCGGACTGAAGGAGCTGCCCATGAGAAATTTACAGGAAATCCTGCATGGC
GCCGTGCGGTTCAGCAACAACCCTGCCCTGTGCAACGTGGAGAGCATCCAGTGG
CGGGACATAGTCAGCAGTGACTTTCTCAGCAACATGTCGATGGACTTCCAGAACC
ACCTGGGCAGCTGCCAAAAGTGTGATCCAAGCTGTCCCAATGGGAGCTGCTGGG
GTGCAGGAGAGGAGAACTGCCAGAAACTGACCAAAATCATCTGTGCCCAGCAGT
GCTCCGGGCGCTGCCGTGGCAAGTCCCCCAGTGACTGCTGCCACAACCAGTGTGC
TGCAGGCTGCACAGGCCCCCGGGAGAGCGACTGCCTGGTCTGCCGCAAATTCCG
AGACGAAGCCACGTGCAAGGACACCTGCCCCCCACTCATGCTCTACAACCCCAC
CACGTACCAGATGGATGTGAACCCCGAGGGCAAATACAGCTTTGGTGCCACCTG
CGTGAAGAAGTGTCCCCGTAATTATGTGGTGACAGATCACGGCTCGTGCGTCCGA
GCCTGTGGGGCCGACAGCTATGAGATGGAGGAAGACGGCGTCCGCAAGTGTAAG
AAGTGCGAAGGGCCTTGCCGCAAAGTGTGTAACGGAATAGGTATTGGTGAATTT
AAAGACTCACTCTCCATAAATGCTACGAATATTAAACACTTCAAAAACTGCACCT
CCATCAGTGGCGATCTCCACATCCTGCCGGTGGCATTTAGGGGTGACTCCTTCAC
ACATACTCCTCCTCTGGATCCACAGGAACTGGATATTCTGAAAACCGTAAAGGA
AATCACAGGGTTTTTGCTGATTCAGGCTTGGCCTGAAAACAGGACGGACCTCCAT
GCCTTTGAGAACCTAGAAATCATACGCGGCAGGACCAAGCAACATGGTCAGTTT
TCTCTTGCAGTCGTCAGCCTGAACATAACATCCTTGGGATTACGCTCCCTCAAGG
AGATAAGTGATGGAGATGTGATAATTTCAGGAAACAAAAATTTGTGCTATGCAA
ATACAATAAACTGGAAAAAACTGTTTGGGACCTCCGGTCAGAAAACCAAAATTA
TAAGCAACAGAGGTGAAAACAGCTGCAAGGCCACAGGCCAGGTCTGCCATGCCT
TGTGCTCCCCCGAGGGCTGCTGGGGCCCGGAGCCCAGGGACTGCGTCTCTTGCCG
GAATGTCAGCCGAGGCAGGGAATGCGTGGACAAGTGCAACCTTCTGGAGGGTGA
GCCAAGGGAGTTTGTGGAGAACTCTGAGTGCATACAGTGCCACCCAGAGTGCCT
GCCTCAGGCCATGAACATCACCTGCACAGGACGGGGACCAGACAACTGTATCCA
GTGTGCCCACTACATTGACGGCCCCCACTGCGTCAAGACCTGCCCGGCAGGAGTC
ATGGGAGAAAACAACACCCTGGTCTGGAAGTACGCAGACGCCGGCCATGTGTGC
CACCTGTGCCATCCAAACTGCACCTACGGATGCACTGGGCCAGGTCTTGAAGGCT
GTCCAACGAATGGGCCTAAGATCCCGTCCATCGCCACTGGGATGGTGGGGGCCC
TCCTCTTGCTGCTGGTGGTGGCCCTGGGGATCGGCCTCTTCATGCGAAGGCGCCA
CATCGTTCGGAAGCGCACGCTGCGGAGGCTGCTGCAGGAGAGGGAGCTTGTGGA
GCCTCTTACACCCAGTGGAGAAGCTCCCAACCAAGCTCTCTTGAGGATCTTGAAG
GAAACTGAATTCAAAAAGATCAAAGTGCTGGGCTCCGGTGCGTTCGGCACGGTG
TATAAGGGACTCTGGATCCCAGAAGGTGAGAAAGTTAAAATTCCCGTCGCTATC
AAGGAATTAAGAGAAGCAACATCTCCGAAAGCCAACAAGGAAATCCTCGATGA
AGCCTACGTGATGGCCAGCGTGGACAACCCCCACGTGTGCCGCCTGCTGGGCAT
CTGCCTCACCTCCACCGTGCAGCTCATCACGCAGCTCATGCCCTTCGGCTGCCTC
CTGGACTATGTCCGGGAACACAAAGACAATATTGGCTCCCAGTACCTGCTCAACT
GGTGTGTGCAGATCGCAAAGGGCATGAACTACTTGGAGGACCGTCGCTTGGTGC
##STR00002##
AGAATCTATACCCACCAGAGTGATGTCTGGAGCTACGGGGTGACTGTTTGGGAG
TTGATGACCTTTGGATCCAAGCCATATGACGGAATCCCTGCCAGCGAGATCTCCT
CCATCCTGGAGAAAGGAGAACGCCTCCCTCAGCCACCCATATGTACCATCGATGT
CTACATGATCATGGTCAAGTGCTGGATGATAGACGCAGATAGTCGCCCAAAGTT
CCGTGAGTTGATCATCGAATTCTCCAAAATGGCCCGAGACCCCCAGCGCTACCTT
GTCATTCAGGGGGATGAAAGAATGCATTTGCCAAGTCCTACAGACTCCAACTTCT
ACCGTGCCCTGATGGATGAAGAAGACATGGACGACGTGGTGGATGCCGACGAGT
ACCTCATCCCACAGCAGGGCTTCTTCAGCAGCCCCTCCACGTCACGGACTCCCCT
CCTGAGCTCTCTGAGTGCAACCAGCAACAATTCCACCGTGGCTTGCATTGATAGA
AATGGGCTGCAAAGCTGTCCCATCAAGGAAGACAGCTTCTTGCAGCGATACAGC
TCAGACCCCACAGGCGCCTTGACTGAGGACAGCATAGACGACACCTTCCTCCCA
GTGCCTGAATACATAAACCAGTCCGTTCCCAAAAGGCCCGCTGGCTCTGTGCAGA
ATCCTGTCTATCACAATCAGCCTCTGAACCCCGCGCCCAGCAGAGACCCACACTA
CCAGGACCCCCACAGCACTGCAGTGGGCAACCCCGAGTATCTCAACACTGTCCA
GCCCACCTGTGTCAACAGCACATTCGACAGCCCTGCCCACTGGGCCCAGAAAGG
CAGCCACCAAATTAGCCTGGACAACCCTGACTACCAGCAGGACTTCTTTCCCAAG
GAAGCCAAGCCAAATGGCATCTTTAAGGGCTCCACAGCTGAAAATGCAGAATAC
CTAAGGGTCGCGCCACAAAGCAGTGAATTTATTGGAGCATGA
The thymidine residue subject to the L858R mutation is bolded and in parentheses.
Forty-Eight Short, Directly Labeled Probes
The reverse complements of the underlined sequences in the EGFR cDNA sequence above. Twenty-four are 5′ to the shaded sequence that includes the nucleotide (T) subject to mutation, and 24 are 3′ to that sequence.
Right arm-donating hairpin probe EGFR 3.1 (mutant)
(SEQ_ID No. 43)
GTTACAGACGACTCCCACAGTCC GTTTGGCC(C)GCCCAAAATGGACT.
The sequences that form a stem are underlined. The nucleotides that form a single-stranded loop and are complementary to the mutant target are bolded. The nucleotide of the single-nucleotide mutation is in parentheses.
Left arm-donating hairpin probe EGFR 3.0
(wild-type)
(SEQ ID N. 44)
TAGGTGTTTGGCC(A)GCCCAAAATACCTACCTCGTAAATCCTCATCAAT
CATC.
The sequences that form a stem are underlined. The nucleotides that form a single-stranded loop and are complementary to the wild-type target are bolded. The nucleotide that is subject to mutation is in parentheses.
Right acceptor hairpin probe EGFR 3.0
(SEQ ID No. 45)
CTCCTTCTGCATGGTATTCTTTCTCTTCCGCACCCAGCAGGACT
GTGGGAGTCGTCTGTAACTACTTCATGTTACAGACGACTCCCAC.
The sequences that form a stem are underlined. The nucleotides that are complementary to the mutant and wild-type targets are bolded.
Left acceptor hairpin probe EGFR 3.0
(SEQ ID No. 46)
CCTCGTAAATCCTCATCAATCATCCAGTAAACCGCCGATGATTGAT
GAGGATTTAGGAGGTAGGTCTGTGATCTTGACATGCTGCGGTGT.
The sequences that form a stem are underlined. The nucleotides that are complementary to the mutant and wild-type targets are bolded.
The interacting hairpin probes were obtained from IDT DNA Inc. and then purified by polyacrylamide gel electrophoresis as described in Example 4. The right arm-donating hairpin probes and right acceptor probes were heated to 95° C. for 2 minutes and allowed to cool at room temperature for 10 min in 2×SSC (in separate tubes) to ensure that they have properly formed their respective hairpins. The short, directly labeled probes were obtained with 3′ amino groups from Biosearch LGC and then coupled to Texas Red dye. The labeled probes were purified as described by Raj et al. (2008).
The cells were cultured on coverslips, fixed and permeabilized as described in Example 1.
In a first experiment the probe hybridization reaction mixture (50 μl) contained 25 ng of pooled short, directly labeled probes, 5 ng each of right arm-donating hairpin probe EGFR 3.1 (mutant), left arm-donating hairpin probe EGFR 3.1 (wild-type), right acceptor hairpin probe EGFR 3.0, and left acceptor hairpin probe EGFR 3.0. In addition to these probes, the hybridization mixture also contained 10% dextran sulfate (Sigma), 1 mg/ml Escherichia coli tRNA (Sigma), 2 mM ribonucleosidevanadyl complex (New England Biolabs, Ipswich, Mass.), 0.02% RNase-free bovine serum albumin (Ambion), 10% formamide and 2×SSC. This hybridization reaction mixture was placed over a stretched parafilm, and a coverslip was laid over it with cells facing down, followed by incubation at 50° C. overnight in a humid chamber. The coverslips were washed twice with probe wash buffer and once with HCR buffer.
In a second experiment probes hybridization was performed in two steps, and the concentration of the arm-donating hairpin probes was increased. In the first step the hybridization reaction mixture included the left and right acceptor probes but not the arm-donating hairpin probes. After this hybridization, which was performed under the same conditions as specified above but for 6 hr, excess acceptor probes were removed by two successive washes of coverslips with the probe wash buffer. Thereafter, a second hybridization was performed with a reaction mixture that included 20 ng of each of the right and left arm-donating hairpin probes but not the acceptor probes. The second hybridization was performed overnight. The Texas Red-labeled probes were included in both hybridization reactions. Excess arm-donating probes were removed by washing.
Next, in both experiments, HCR amplification was performed in HCR buffer as described in Example 1. The HCR reaction mixture included two sets of HCR hairpin oligonucleotides: Cy5-labeled H3 and H4, and TMR-labeled H1 and H2. After removing excess (unused) HCR hairpin oligonucleotides, the coverslips were imaged with a 63× objective with 1.4 numerical aperture in a Zeiss Axiovert microscope in DIC, DAPI, TMR, Texas Red and Cy5 channels, using a Prime Photometric sCMOS camera. In the TMR, Texas Red and Cy5 channels 16 optical sections separated from each other by 0.2 μm were acquired. These z-stacks were analyzed by a custom MATLAB image processing program that identifies spots in 3-D in each channel and then identifies the spots that are co-localized between each pairs of channels (Vargas et al. 2011). Spots that were co-localized in all three spots were rarely found.
Images and image analyses from the first experiment are presented from one cell each of cell line H1975 (top row) and the HeLa cell line (bottom row) in
Table 2 presents the results of counting spots in images of single cells from the two experiments. The number of spots are presented in different categories of spots: the total number of Texas Red spots, the number of TMR spots that were not co-localized (“Alone”) with Texas Red spots, the number of Cy5 spots that were not co-localized with Texas Red spots, the number of TMR spots that were co-localized with Texas Red spots, and the number of Cy5 spots that were co-localized with Texas Red spots. The top two rows are the counts of single cells in the first experiment (one-step probes hybridization), namely the cells shown in
TABLE 2
Number of spots detected in single cells
Texas
Texas Red
Texas Red
Red
TMR
Cy5
Co-localized
Co-localized
Total
Alone
Alone
with TMR
with Cy5
One-step
Exemplary
H1975
58
22
16
9
7
hybridization
Cells
HeLa
84
16
2
23
0
(FIG. 15)
Averages
H1975
42.5
17.0
13.2
4.9
9.4
from 60
HeLa
18.3
10.5
4.9
3.4
0.2
cells
Two-step
Averages
H1975
54.7
4.1
4.7
3.6
12.9
hybridization
from 50
HeLa
20.1
4.1
0.9
3.4
0.5
cells
Tyagi, Sanjay, Marras, Salvatore A. E.
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